RU2731009C1 - Multi-level earthquake-proof parking lot - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to buildings and structures, in particular, to multi-level parking lots buildings. Multi-level earthquake-resistant parking lot consisting of vertical reinforced concrete bearing racks and inter-floor reinforced concrete floor slabs, foundation support plate reinforced with piles, cargo-and-passenger lift in the middle of the building, as well as a two-lane road between floors. According to the outer shape the building is made with a truncated cone with a larger diameter in the foundation part, which is supplemented with a plate in the building base, and between said foundation plate, reinforced with piles, and additional board of building base provided seismic clearances, filled with inert material in form of sand cushion, and height of building is made equal to average diameter, building consists of several links, besides, the boundary of two adjacent links is an inter-floor monolithic reinforced concrete plate, which is monolithically fixed to said vertical reinforced concrete bearing racks and to walls of the cargo-passenger elevator shaft, wherein said vertical reinforced concrete bearing racks are arranged with a certain circumferential pitch in two rows: the first one is along the perimeter of the building, and the second one is closer to the centre to the cargo-passenger elevator.

EFFECT: object of the present invention is to increase economy, capacity and earthquake-proofing of a parking building.

5 cl, 1 dwg

Description

The invention relates to the field of buildings and structures, in particular to multi-level buildings for parking lots.

Known multi-level parking lots, which are four-, five-storey buildings, "boxes", rectangular with a road between floors, but these buildings in terms of the specific ratio of the number of parked cars to the cost of building materials are quite small, and therefore not effective, to besides, they are not earthquake resistant and there is no cargo-passenger lift.

Known multi-level parking garage for cars [1], including an entrance, a lift with locks for wheels, boxes, contains a frame with decorative walls, boxes have towing and fixing devices.

The disadvantage [1] is that the car is lifted into the parking space with a lifting device, which is fraught with a possible accident in the absence of energy for lifting or lowering during an urgent evacuation from fires or other situations, and also increases the parking time.

Known multi-level carousel-screw parking [2], according to which the acceptance and delivery of cars is carried out in one door, on each floor, with the supply of the required space with a car or free space for receiving one carousel movement of the circular platform until it is aligned with the door of the building wall, lifting cars to each floor is made without changing direction on its own along independent specialized ramps to a horizontal platform opposite the door on each floor.

The disadvantage [2] is that the mechanism for raising and leaving cars from the parking lot does not provide proper high-speed parking, which is fraught with accidents and tragedies if an urgent evacuation is necessary or reaching the parking place in an emergency.

Known multi-storey car park [3], in which from the entrance to the parking lot to the parking space, has a mechanized lift containing a vertical endless chain conveyor with platforms cantilevered on the chains of the conveyor, while the floors of the parking lot communicate with each other through the aforementioned powered lift.

The disadvantage [3] lies in the fact that the entry or exit directly depends on the serviceability of the powered lift and the source of electricity for its operation, as well as the limited speed and intensity of the number of vehicles changing.

The aim of the present invention is to improve the efficiency, capacity and seismic resistance of a car park building.

The goal can be achieved by the fact that a multi-level earthquake-resistant car park building, consisting of vertical reinforced concrete bearing racks and interfloor reinforced concrete floor slabs, a foundation base plate reinforced with piles, a cargo-passenger elevator, in the middle of the building, as well as a two-lane road between floors, is made by a large truncated cone in its outer form. diameter, in the foundation part, which is supplemented by a slab at the base of the building, and in height equal to the average diameter, the building consists of several links, moreover, the border of two adjacent links is an interfloor monolithic reinforced concrete slab, which is monolithically fixed to the above-mentioned vertical reinforced concrete bearing racks and to the walls cargo-passenger elevator shafts, while the mentioned vertical reinforced concrete bearing racks are located in two circles with a certain pitch, the first with a diameter equal to the circumference of the upper part of the building, the second is located in the middle between the first and the wall of the cargo-passenger elevator; in addition, it is supplemented with cable-stayed suspensions of interfloor reinforced concrete floor slabs located in the above-mentioned links of the building, while the ends of the interfloor reinforced concrete floor slabs are located with a certain seismic gap on embedded protrusions, which are provided on vertical reinforced concrete bearing racks and on the walls of the cargo-passenger elevator shaft, while the upper the ends of the cables are fixed to a special metal structure, resting on the upper ends of the vertical reinforced concrete bearing racks and on the end of the wall of the cargo-passenger elevator shaft, and the lower ends of the cables, passed through specially provided holes in the interfloor monolithic reinforced concrete slabs, the boundaries of the links, are fixed to the provided mounting nodes on the mentioned additional building base plate; for the seismic resistance of the building, seismic gaps are provided between the mentioned foundation base plate, reinforced with piles, and the additional base plate of the building, as well as between the side part of the building foundation and the reinforced concrete wall of the foundation pit, while the gaps are filled with a certain inert material and an umbrella slope is provided above the side seismic gap along the perimeter of the building; in terms of safety, along the outer circumference of the above-mentioned interfloor monolithic reinforced concrete slabs and interfloor reinforced concrete floor slabs, a strong reinforced concrete fence with a height of at least one meter is provided; The two-lane road between the floors is located in an arc, with alternating entrances and exits on the floor, offset by 180 ° around the circumference, while it is provided for securing it with metal-roll racks, to the interfloor monolithic reinforced concrete slabs, the boundaries of the building links.

FIG. 1 shows:

1 - trusses of a special metal structure of a triangular shape;

2 - shaft of the cargo-passenger elevator;

3 - cable-stayed suspension of precast concrete interfloor slabs;

4 - fastening unit for cable-stayed suspension of interfloor reinforced concrete floor slabs;

5 - additional base plate for the building;

6 - interfloor monolithic reinforced concrete slab, border between adjacent links;

7 - foundation base plate, reinforced with piles;

8 - seismic gap ("sinus") between the side of the building foundation and the reinforced concrete wall of the foundation pit, filled with inert material, and on top of the umbrella slope along the building perimeter;

9 - piles;

10 - seismic gap between the foundation base plate, reinforced with piles, and the supplemented base plate of the building, (sand cushion);

11 - two-lane road;

12 - embedded protrusions on the bearing reinforced concrete racks 13 and the wall of the cargo-passenger elevator 2;

13 - bearing reinforced concrete racks located with a certain pitch along the outer circumference, equal to the circumference of the upper part of the building and the inner circumference; in the middle, between the outer circumference and the wall of the shaft of the cargo-passenger elevator 2;

14 - entry areas.

The claimed technical solution works as follows.

Cars enter the building through 14 open entrances along the entire perimeter of the first floor. They rise along one lane of the two-lane road 11, drive in a circle to the diametrically opposite side, where the next rise to the next floor is located, then they also drive along an arc to the diametrically opposite side where there will be a rise to the next floor, the driver finds his parking place, puts the car in the parking anti-theft device, which in turn does not allow, also, unauthorized displacement in case of an earthquake. All cars on floors are located along the radius of the building. If it is impossible to exit or ascend on its own in the center of the floor, there is a shaft 2, a cargo-passenger elevator, two freight elevators 4 × 3 m. And two passenger elevators 2 × 1 m. The parking floors are ventilated by natural air flow, since the fence is provided along the outer circumference along the perimeter of the floor, with a height fencing at least 1 meter, the rest of 2.5 meters in height is possibly fenced, for example, with a net, the height of each floor 3.5 meters is designed to accommodate body vehicles.

In the event of an earthquake, the following anti-seismic measures are provided for the gap 8 and 10 between the foundation slab 7 reinforced with piles 9 and the additional slab 5 of the base of the building with a certain inert material (sand cushion) with a layer thickness of at least 10 cm, and the foundation part of the building is recessed into the pit at least 5 floors, between the outer side part of the foundation and the reinforced concrete wall of the pit, the “sinus” is filled with a certain inert material, which is closed from above by an umbrella slope along the perimeter of the building; in the event of an earthquake, the building may allow vertical, horizontal vibrations or rotations along the axis. To extinguish the vibration energy in the ground floors, the possibility of pendulum vibration of the interfloor reinforced concrete floor slabs 6 is provided due to their cable-stayed suspension 3, as well as due to the provided seismic gap at its ends.

Interfloor reinforced concrete floor slabs are installed with supporting parts, at the ends, on the provided embedded protrusions 12 on the vertical reinforced concrete bearing pillars of the building, and the vertical reinforced concrete bearing pillars of the building are placed with a certain pitch along the circumference in two rows, the first along the perimeter of the building, and the second closer to the center , to the cargo-passenger elevators.

Interfloor reinforced concrete slabs are equipped with attachment points for 4 cable-stayed suspension, buildings, while the cables are passed through the provided through holes on the interfloor monolithic reinforced concrete slabs, the boundaries between adjacent links.

Byte hangers are fixed in the upper part of the building to the trusses 1 of a special metal structure of a triangular shape, resting on the upper ends of the vertical reinforced concrete bearing racks 13, and in the lower part of the building, the ends of the cables are passed through specially provided holes in the interfloor monolithic reinforced concrete slabs, the boundaries of the links are fixed to the provided assemblies on an additional building base plate;

Due to the provided seismic gaps, displacement of both the slabs and the building is possible, the energy of the soil vibrations is absorbed and the stability of the building increases. The economy of the building is achieved due to the geometry of the building, in which the average diameter is equal to the height of the building.

Used sources

1. RF patent No. 107246, IPC E04H 6/08. Priority from 31.08.2010. Published on August 10th, 2011. Description of the patent.

2. RF patent No. 2398946, IPC E04H 6/00. Priority from 10.11.2008. Published on September 10, 2010. Description of the patent.

3. Application for invention No. 2005137949/03. Priority from 07.12.2005. Published on February 20, 2008. Formula.

Claims (5)

1. A multi-level earthquake-resistant parking lot, consisting of vertical reinforced concrete bearing racks and interfloor reinforced concrete floor slabs, a foundation base plate reinforced with piles, a cargo-passenger elevator in the middle of the building, as well as a two-lane carriageway between floors, characterized in that the building is made with a truncated cone in its external shape a large diameter in the foundation part, which is supplemented by a slab at the base of the building, and between the said foundation slab, reinforced with piles, and an additional slab of the building base, seismic gaps are provided, filled with an inert material in the form of a sand cushion, and the height of the building is equal to the average diameter, the building consists of several links, and the border of two adjacent links is an interfloor monolithic reinforced concrete slab, which is monolithically fixed to the mentioned vertical reinforced concrete bearing racks and to the walls of the cargo-passenger elevator shaft, while the mentioned vertical reinforced concrete not The actual racks are placed with a certain pitch along the circumference in two rows: the first one is along the perimeter of the building, and the second is closer to the center to the cargo-passenger elevator. 2. A multi-level earthquake-resistant parking lot according to claim 1, characterized in that the building is supplemented with cable-stayed suspensions of interfloor reinforced concrete floor slabs located in the said links of the building, and the ends of the interfloor reinforced concrete floor slabs are located with a certain seismic gap on embedded projections, which are provided on vertical reinforced concrete bearing racks and on the walls of the cargo-passenger elevator shaft, while the upper ends of the cables are fixed to the metal structure resting on the upper ends of the vertical reinforced concrete bearing racks and on the end of the wall of the cargo-passenger elevator shaft, and the lower ends of the cables are passed through specially provided holes in the interfloor monolithic reinforced concrete slabs of the link boundaries and fixed to the provided assemblies on the said additional building base plate. 3. A multi-level seismic-resistant parking lot according to claim 1, characterized in that seismic gaps are provided between the said foundation base plate, reinforced with piles, and an additional base plate of the building, as well as between the side part of the building foundation and the reinforced concrete wall of the foundation pit, while the gaps are filled with inert material in the form of a sand cushion and an umbrella slope along the perimeter of the building is provided above the lateral seismic gap. 4. A multi-level earthquake-resistant parking lot according to claim 1, characterized in that a strong reinforced concrete fence with a height of at least one meter is provided along the outer circumference of the mentioned interfloor monolithic reinforced concrete slabs and interfloor reinforced concrete floor slabs. 5. A multi-level earthquake-resistant parking lot according to claim 1, characterized in that the said two-lane road between the floors is located in an arc with alternating entrances and exits on the floors, offset by 180 ° around the circumference, while it is provided for fixing it with racks made of rolled metal to interfloor monolithic reinforced concrete slabs of the boundaries of the building links.

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