RU94603U1 - SPATIAL COVERING OF BUILDINGS AND STRUCTURES - Google Patents

Abstract

 1. The spatial coating of buildings and structures, made in the form of an airtight shell, filled with gas lighter than air and attached by tensioning fasteners, such as cables or braces, to the holding elements, the fastening elements of the shell are made and arranged to cover large spaces, buildings or structures, this hanging shell is fixed in space by attaching ropes or extensions using pillars, masts, towers placed around the perimeter of the shell or structurally x elements of buildings and structures, the height of which is greater than or equal to the upper level of the shell, and the shell is fastened simultaneously to the upper and lower parts of poles, masts, towers or structural elements of buildings and structures, as well as to retaining elements located on the surface of the earth or structural elements . ! 2. The spatial coating of buildings and structures of claim 1, characterized in that for mounting and stabilizing the shell at the design height, cranes are used installed around the perimeter of the gas-filled shell. ! 3. The spatial coating of buildings and structures according to claim 1, characterized in that under the shell between the poles, masts, towers or structural elements of buildings and structures, cables or cables are stretched to prevent the gas-filled shell from falling if it is depressurized. ! 4. The spatial coating of buildings and structures of claim 1, characterized in that the gas-filled shell is made in the form of an inverted plate with a surface concave from its lower side, providing additional lifting force. ! 5. Prostra

Description

The utility model relates to construction and can be used for coating sports facilities, hangars, exhibition halls, concert and other structures using hermetic shells of various shapes filled with gas lighter than air.

Such shells can be used as a large-span coating to protect against precipitation, solar radiation and other adverse environmental conditions, for which a gas-filled shell hanging in the air must be firmly fixed to the ground or structures at a given height.

Known sun shelter for outdoor sports and entertainment facilities [1], the bearing element of which is an aerostat filled with light gas, fixed with halyards and stretch marks to the covered structure. The construction is equipped with a mesh fixed to the halyards with tapes that act as blinds for sun protection. The disadvantage of this design is its mobility under the influence of atmospheric phenomena, as well as the inability to use it to protect against rain and wind and low temperatures.

A spatial pneumatic coating is also known [2], the bearing element of which is a torus-shaped shell filled with gas lighter than air. A double or triple membrane is placed inside the supporting element, which performs the function of a coating, the curvature of which is controlled by filling the space between these membranes with air. To fix the coating at a certain height, stretch marks are used that connect the supporting elements and the structures of the building to be covered. The disadvantage of this design is its complexity and instability in the horizontal and vertical direction, because the flexibility of the cables does not allow the shell to be rigidly stabilized under the influence of changing wind loads and lifting force.

It is also known that a cover made of a gas-filled lighter than air shell (balloon) in the form of an oval disk [3], covering the entire hole in the coating above the football stadium. The balloon is attached to the structures of the building covered by flexible cables. As in previous cases, the known technical solution does not provide stability and motionlessness of the coating structure.

Closest to the proposed technical solution is the aerostatic support of the roof of the structure [4], containing an aerostat, a transparent flexible coating, ropes and winches, and the coating is made in the form of a canopy of individual scarves connected to each other, each of which is attached to the surface of the aerostat with one end , and the other end using ropes to winches installed on the structure of the structure.

The winches are equipped with an electric drive, and the winches are controlled by a computer.

The roof is equipped with sensors: rope tension, gas pressure in the aerostatic support, as well as changes in weather conditions, while these sensors are also connected to a computer.

A disadvantage of the known technical solution is the structural and operational complexity, unreliability and high cost of the electronic stability system.

The purpose of the proposed technical solution is to simplify the structural and operational complexity through the use of mechanical methods of stabilization of a gas-filled shell, as well as the use of structural features (sizes, shapes) that allow achieving optimal technical parameters and best ensure the performance of the coating functions of large spaces, buildings and structures .

The technical result, which consists in eliminating the noted drawbacks of the prototype [4], is achieved in the proposed spatial coating of buildings and structures made in the form of an airtight shell filled with gas lighter than air and attached with tensioning fasteners, for example, cables or extensions, to the holding elements, that the fastening elements of the shell are made and arranged to provide coverage for large spaces, buildings or structures, while the hanging shell is fixed in the space of means m fastening of cables or extensions using posts, masts, towers or structural elements of buildings and structures placed around the perimeter of the shell, the height of which is greater than or equal to the upper level of the shell, and the shell is fastened to the upper and lower parts of the posts, masts, towers or structural elements buildings and structures, as well as to retaining elements located on the surface of the earth.

The technical result, which consists in reducing the installation time of coatings, is achieved by the fact that for mounting and stabilizing the shell at the design height, cranes are used installed around the perimeter of the gas-filled shell.

An additional technical result, which is to increase the safety of coatings, is achieved by the fact that under the shell, cables or cables are stretched between poles, masts, towers or structural elements of buildings and structures to prevent the gas-filled shell from falling if it is depressurized.

Improving performance is also achieved by the fact that the gas-filled shell is made in the form of an inverted plate with a surface concave from its lower side, providing additional lifting force, and heating elements are fixed on the inner surface of the shell.

The expansion of operational capabilities is also achieved by the fact that the gas-filled shell is made of a translucent or transparent material.

An additional increase in the safety of the coating is achieved by the fact that the gas-filled shell is partitioned with installed internal partitions.

The expansion of the functionality of the coating due to the use of a large coating area as an alternative energy source is achieved by converting sunlight to electricity onto the outer surface of the gas-filled shell.

The essence of the utility model is illustrated by drawings, where:

- figure 1 presents the option of attaching the shell using the walls of the structure, pillars and racks;

- figure 2 presents the option of attaching the shell using cranes;

- figure 3 presents a mounting option for a convex shell shape using cranes;

The spatial coating (figure 1, 2, 3) is made in the form of a sealed shell 1, filled with gas lighter than air and attached with tension fasteners, for example, cables or braces 2, to the holding elements 3.

The fastening elements 2 of the shell 1 are made and arranged to cover large spaces, buildings or structures, while the hanging shell 1 is fixed in space by attaching ropes or extensions 2 using the posts and masts 4, towers 5 or structural elements of buildings placed around the perimeter of the shell 1 and structures 6, the height of which is greater than or equal to the upper level of the shell 1, and the shell is mounted at the same time to the upper and lower parts of the posts, masts 4, towers 5 or structural elements 6 Danian and structures, as well as retaining elements 3, located on the ground surface or structural elements.

Under the shell 1 between the poles, masts, towers 4 and 5 or structural elements of buildings and structures 6, cables or cables 7 are stretched to prevent the gas-filled shell 1 from falling if it is depressurized.

The proposed coating can be used for large-area hangars for placement in them, for example, aircraft 8 (figure 1).

The coating can be used for sports facilities, for example, swimming pools with passages and stands for spectators 10 and with towers 11.

In another constructive embodiment of the coating (Fig. 3), the gas-filled shell 1 is made in the form of an inverted plate with a surface concave from its lower side, providing additional lifting force.

In this case, heating elements are fixed on the inner surface of the shell 1 (not shown in the drawings).

The gas-filled shell 1 is made of a translucent or transparent material.

The cables 2, stabilizing the gas-filled shell 1, are equipped with winches (not shown in the drawings), providing the ability to change the installation height of the shells 1 above the covered building or structure.

To increase reliability and safety, the gas-filled shell 1 is made partitioned with internal partitions (not shown in the drawings).

To use a large area of the gas-filled shell 1 on its outer surface are fixed converters of sunlight into electricity (not shown in the drawings).

The device operates as follows.

The gas-filled shell 1 is filled with gas lighter than air and is made in the form of a round, oval or any other shape in terms of a disk or a polyhedron, the length and width of which are accepted as maximum and the minimum as possible, which ensures the maximum coverage area.

The coating shell 1 is made of a film of strong polymer material in the factory and is delivered to the place of suspension and installation by towing through the air.

The shell 1 hanging in the air is suspended above a space, structure or building that serves as a sports arena, theater, circus, exhibition or conference hall, museum, greenhouse, water park, train station, temple, market, field for public events, hangar, workshop, etc. .d.

In order to stabilize the shell 1 in space at a given height, it is attached by ropes 2 to the ground or structures of buildings or structures 3 through special poles, masts, towers 4 and 5 or through the structures of buildings 6, the height of which is greater than or equal to the height of the shell 1 (Fig. one). In this case, the poles, masts, towers 4 and 5 or buildings 6 should be located along the perimeter of the shell 1, which should be fixed to the top and base of poles, masts, towers or buildings. Such fastening prevents the instantaneous fall of the shell 1 in case of its depressurization. For the same purpose, cable-ropes 7 can be used, stretched under the coating sheath between poles, masts, towers or building structures (Fig. 1).

Poles, masts, towers 4 and 5 or buildings 6, to which the shell 1 is attached, can be used to install lighting, sound reinforcing or other equipment.

As the towers can be used cranes 9 (figure 2 and figure 3), which carried out the construction of the covered building or structure.

In order to create additional lifting force with warm air generated during operation, the shell 1 can be made in the form of an inverted plate concave from the bottom side (figure 3).

Heating elements are fixed on the inner surface of the shell 1 (not shown in the drawings), which allows heating the gas inside the shell, which, expanding, further increases the lifting force.

Converters of sunlight into electricity (not shown in the drawings) are fixed on the outer surface of the gas-filled shell, which allows to expand the functionality of the coating due to the use of its large area.

The proposed coating allows you to cover spaces of significantly larger sizes than known coatings. At the same time, the quality of the coating can significantly increase, because the shell is manufactured in the factory, and delivery to the installation site is carried out in full factory readiness by towing by air.

The utility model can significantly reduce time and labor costs for the coating device, as well as for its dismantling and moving to another place.

Loads from the weight of the coating on the walls and foundations, as well as on the base of buildings and structures tend to zero or are directed upward due to the lifting force of the gas-filled shell. These properties provide significant advantages, as well as cost savings and labor costs under difficult and particularly difficult construction conditions, in particular:

- in remote areas, remote from the bases of industrial construction;

- on a difficult steep terrain;

- on weak and landing soils;

- on permafrost;

- with high seismic activity;

- with special environmental, archaeological, geological and other requirements for the conservation of soil, topography of the plant or cultural layer,

- if necessary, as soon as possible to arrange temporary coverage, and if necessary, then move it to other places, for example, for olympiads, championships, public celebrations;

- if necessary, urgent arrangement of temporary coverage of hangars and workshops, temporary shelters, etc.

The utility model also provides the opportunity to create vivid, expressive, imaginative and memorable architectural solutions for public buildings and structures.

Information sources:

1. RF patent No. 2032053, MKI E04H 15/14, E04H 15/00 from 1995

2. USSR author's certificate No. 1260492, MKI E04 15/20 of 1986

3. Japan patent No. 56421, MKI E04H 15/20 E04H 7/1 of 2006

4. RF patent No. 56421, MKI E04B 1/00 of 2006

Claims (9)

1. The spatial coating of buildings and structures, made in the form of an airtight shell, filled with gas lighter than air and attached by tensioning fasteners, such as cables or braces, to the holding elements, the fastening elements of the shell are made and arranged to cover large spaces, buildings or structures, this hanging shell is fixed in space by attaching ropes or extensions using pillars, masts, towers placed around the perimeter of the shell or structurally x elements of buildings and structures, the height of which is greater than or equal to the upper level of the shell, and the shell is fastened simultaneously to the upper and lower parts of poles, masts, towers or structural elements of buildings and structures, as well as to retaining elements located on the surface of the earth or structural elements . 2. The spatial coating of buildings and structures of claim 1, characterized in that for mounting and stabilizing the shell at the design height, cranes are used installed around the perimeter of the gas-filled shell. 3. The spatial coating of buildings and structures according to claim 1, characterized in that under the shell between the poles, masts, towers or structural elements of buildings and structures, cables or cables are stretched to prevent the gas-filled shell from falling if it is depressurized. 4. The spatial coating of buildings and structures of claim 1, characterized in that the gas-filled shell is made in the form of an inverted plate with a surface concave from its lower side, providing additional lifting force. 5. The spatial coating of buildings and structures of claim 5, characterized in that heating elements are fixed on the inner surface of the shell. 6. The spatial coating of buildings and structures of claim 1, characterized in that the gas-filled shell is made of a translucent or transparent material. 7. The spatial coating of buildings and structures of claim 1, characterized in that the gas-filled shell is made partitioned with installed internal partitions. 8. The spatial coating of buildings and structures of claim 1, characterized in that on the outer surface of the gas-filled shell are fixed converters of sunlight into electricity. 9. The spatial coating of buildings and structures of claim 1, characterized in that the cables stabilizing the gas-filled shell are equipped with winches that provide the ability to change the height of the installation of shells above the covered building or structure.