RU2507357C1 - Covered stadium - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: stadium design includes angular buildings, between which buildings are erected along its perimetre with ordinary stands at the bottom and cantilever tier stands above them. The cover is equipped with lifting-transport mechanisms for arena transportation. At the same time the cover rests against tier stands and onto two longitudinal bearing structures coupled with the frame of angular buildings and making a single structure with them. Works of transformation are carried out with the help of several beam cranes simultaneously along the entire width of the arena.

EFFECT: simplified and cheaper design of a covered stadium, provision of quick transformation.

4 cl, 10 dwg

Description

The invention relates to the construction of universal spectacular structures - indoor stadiums with a sliding cover and its transformation for various events (hereinafter we will talk about grass arenas as the most difficult to transform, although the above is true for any type of arenas).

The famous Lukas Oil Stadium (USA, Indianapolis, http://football.hiblogger.net/authors/stadiums/), the grass arena of which consists of square pallets 2.5 × 2.5 m with grass. For other events, the pallets are removed, releasing the concrete base on which spectator stands for concerts, etc. are mounted. A time-consuming process requiring workers, machinery, cranes and considerable time. To simplify and accelerate the transformation process, an arena rolling out outside the stadium is used (Wembley stadiums, England, Gelredome, Holland). At the same time, the construction of the stadium becomes more complicated, there remain problems with the installation of temporary stands, and the grass field outside the stadium still needs to be protected from atmospheric influences.

For many spectacular events, you need a scene, which is most often collapsible. In some stadiums, the lower part of one of the stands is removed, freeing up the stage (A.Yu. Kistyakovsky “Designing of sports facilities”, M., VSh, 1980, p. 159). The well-known "Transformable tribune" (AS USSR No. 691548, Shogenov S.Kh.), which allows to simplify and speed up the process of stage equipment.

At stadiums, spectators are accommodated in ordinary stands, often to increase capacity, they arrange second, third, etc. tiers with their inclination towards the arena, while the conditions of visibility and comfort are worsening, further complicating the design of the stadium. In theaters, concert halls, etc. they use tiered rows (lodges) on the side and far walls relative to the stage, placing them vertically one above the other. The “Spectacular Building” is known (USSR AS No. 815240, Didenko N.Ya., Shogenov S.Kh.), in which additional rows are arranged in ascending cover at the level of the lower belts.

Another important problem is the device of a wide-span sliding cover for insolation of the internal volume and the grass arena. There are well-known stadiums (Cowboys Stadium USA, Veltms Arena, Germany, etc.), in which transverse cover structures with sliding blocks rest on two main longitudinal supporting structures. The span of longitudinal structures exceeds 160 m, which complicates and increases the cost of the coating as a whole. The famous Gelredome stadium, Holland (http://football.hiblogger.net/authors/stadiums/) is known, in which support walls are adjacent to the corners of the arena, and sliding coating blocks are supported on them through farms. The span of structures is reduced to 120-130 meters, which makes it cheaper.

The closest in technical essence to the proposed solution is the design of Parken Stadium, Denmark (http://football.hiblogger.net/authors/stadiums/), where four buildings are located at the corners of the arena, two longitudinal load-bearing coating structures are supported by racks, adjacent to these buildings, the coating consists of stationary parts above the usual two-tier stands around the arena between the buildings and the sliding part above the arena. An interesting feature of the stadium (as well as the Gelredome stadium) is the exclusion of corner spectator sectors, the visibility conditions of which are the worst (while the capacity still exceeds 40 thousand spectators, the minimum recommended for world and European championships) and the use of corner buildings as public, commercial etc.

The disadvantages of such a solution (like the others described above) include:

1) the obvious difficulties associated with the transformation of the arena and the arrangement of the stage for various entertainment events;

2) the remoteness of a significant part of the audience (especially in the upper rows of the second tier of the stands) from the arena and the deterioration of visibility conditions for many other types of entertainment events;

3) the main longitudinal bearing structures of the coating are independent elements operating according to the beam scheme;

4) there is no single functional concept and its planning, constructive, organizational, etc. implementation, which ultimately limits the capabilities of the structure and increases the cost of its construction and, especially, operation.

The aim of the present invention is to simplify and reduce the cost of the design of the indoor stadium, ensuring the rapid transformation of the structure under various spectacles and creating comfortable conditions for the stay of spectators and participants in events.

This goal is achieved by the fact that the indoor stadium with a rectangular arena, four buildings at its corners, ordinary stands on the long and short sides of the arena between corner buildings with the excess of the first row above the arena, two longitudinal bearing structures of the coating with a stationary part over ordinary stands and a sliding translucent part above the arena, characterized in that along the perimeter of the stadium between the corners there are buildings with ordinary stands below and cantilevered grandstands above them, and cantilevered tiers The tribune in height also has angular buildings on its sides inside the stadium, at one of the ends of the arena there is a transformable tribune, a building of longline stands with an opening to the bottom of the cover, a warehouse of blocks for transforming the arena, and the cover consists of the main longitudinal and transverse load-bearing structures with upper with belts of the same plane, stationary parts of the coating rest on adjacent longitudinal, transverse structures and buildings of longline stands and serve as supports for sliding blocks of the coating when it is opened, while in the coating on longitudinally mounted crane trusses with ways to move suspended crane beams, which extend above the transformed tribune and, resting on racks on the longline stands, overlap the warehouse with support on the structure of the back of the warehouse, being also supporting structures of the stationary covering, are mounted on the lower belts of the main transverse structures this part of the stadium, and the crane beams, providing work across the entire width of the arena, go into the warehouse and back into the openings between the top of the tier stands, the bottom of the cover, the walls of the corner buildings buildings and crane trusses, and in the coating, the main longitudinal bearing structures mate with the frame of the corresponding corner buildings, forming a single structure with them, and the arena transformation blocks are large-sized rectangular constructions with a supporting lattice frame and four corner supports below in the form of racks , some of which have spectators' rows with seats on top, and other blocks have a horizontal floor, which, depending on the events, are installed in a certain place of the crane beam arena and, closing the entire arena, while in the places where the block supports are installed on the bearing base of the grass arena, pallets of grass are previously removed from it.

The given set of essential features of the proposed solution is not described in the literature. The novelty of the solution lies in the fact that buildings along its perimeter with ordinary stands below and cantilever stands above them are introduced into the stadium’s construction between the corners, and the cover is equipped with lifting and transport mechanisms for transforming the arena, while the cover rests on the buildings of the long stands and two longitudinal supporting structures, mating with the frame of corner buildings and making up a single structure with it, and transformation work is carried out using several crane beams simultaneously across the entire width of the arena.

The stadium covering has the main longitudinal and transverse load-bearing structures of the same plane, while the stationary parts, relying on their supporting elements on the longitudinal, transverse load-bearing coating elements and longline stands adjacent to them, are at the same time the supports of the sliding coating blocks when it is extended. These sliding cover blocks have at least four supports in the form of rollers with gearboxes, electric motors and a control system, rely on the rail tracks of the upper belts of the transverse load-bearing structures and move along them in the transverse direction during the sliding-slide coating.

In the coating over the arena, lower crane trusses are installed on the lower belts of the transverse load-bearing structures with paths for moving suspended crane beams, which continue towards the transforming platform.

Longitudinal, transverse bearing elements of the coating and crane trusses are made in the form of paired lattice structures with rods of round pipes, which allows to increase their rigidity without additional connections, simplify the connections between themselves and improve the visual perception of structures. In addition, the transverse structures of the coating and crane trusses to increase their vertical stiffness are accepted as working according to a continuous static scheme.

The tiered and corner buildings on the walls facing the inside of the stadium have horizontal tiered consoles with rows of seats for spectators and a fence. In the simplest case, there is one row of spectators on each tier, and the distance between the tiers in height is sufficient for the viewer to go to full height. Thus, the audience is located on the vertical planes of the buildings of the grandstand and the walls of the corner buildings facing the inside of the stadium, which ensures their maximum approximation to the arena and the best conditions of visibility.

If necessary, the scene device one of the end stands is transformed by A.S. USSR No. 691548 and its revolution is carried out by lifting and transport coating mechanisms, which simplifies the process.

The transformation of the arena consists in the installation of large-sized blocks with crane beams that completely cover it. The blocks eventually form either a horizontal floor (some game sports, dance shows, exhibitions, etc.), or a spectator stall with a bias towards the stage and rows of seats (concerts, movie shows, etc.), or a combination of them ( some shows require a certain floor area and spectator seats). The blocks themselves are rectangular lattice-bearing frames with four supports at the bottom in the form of racks for installation on the base of the arena; moreover, on grass arenas in places where blocks are installed, pallets with grass are previously removed from it. On the base frame of the block, either the floor or the audience rows with seats are mounted on top, while the number of blocks is such that allows for the maximum number of different events.

All blocks are stored in a warehouse, which is located behind the transformed stand and the building of long stands, and their delivery and installation in the arena, as well as reverse transformation, is carried out by crane beams. To do this, a gap is left between the top of the building of the long stands and the bottom of the cover, the crane trusses of the central part of the cover continue above the transforming stand, the building of the long stands with the intermediate stands resting on it, the warehouse and rest on the back side of the warehouse. Thus, the crane beams are moved to the warehouse and back to the arena through the openings formed by the top of the tier stands, the bottom of the cover, the adjoining walls of the corner buildings and the stands of the crane farms. The number of openings is equal to the number of crane beams, and their height allows you to pass a crane beam with a suspended arena block. At the same time, crane farms simultaneously serve as supporting structures for the stationary coating of this part of the stadium.

Such a transformation scheme allows it to be carried out as quickly as possible (in several hours) due to large-sized blocks and the simultaneous operation of several crane beams across the width of the building. This allows you to dramatically expand the capabilities of the stadium to conduct various entertainment events.

Thus, in the given design of the stadium, a single functional concept is implemented, in which all the basic elements are not only clearly interconnected, but also perform additional functions. Buildings of longline stands, bringing spectators closer to the arena, create good visibility of events and comfortable conditions of stay, serve as support for stationary parts of the cover, which, in turn, transfers the weight of the sliding parts. Covering the stadium, performing its main function, is equipped with lifting and transport mechanisms for the transformation of the arena. Crane farms, providing the movement of crane beams, unfasten the main transverse structures from the plane, and those, in turn, fix the main longitudinal elements of the coating in their plane. The latter now constitutes a single structure with corner buildings, which positively affects their work on external influences. The transformation process is not only simplified, but also allows you to expand the list of ongoing activities. Such a clear relationship between the elements of the system and the implementation of the principle of combining functions not only improves its operation as a whole, but also seriously reduces the technical and economic indicators of the design. In this regard, it can be argued that the proposed solution meets the eligibility criteria for the objects of the invention.

The invention is illustrated by drawings, where Figures 1-10 show the coverage and plan of the stadium with longitudinal and transverse sections, the plan of the supporting structures of the coating, fragments of long stands, the plan and scheme of transformation of the stadium and the interface of the main longitudinal structure of the coating with the frame of corner buildings.

The indoor stadium (Figs. 1, 2) has a rectangular arena 1 and corner buildings 2, between which along the perimeter are buildings 3 with ordinary stands 4 and cantilevered grand stands 5, including on the sides of corner buildings 2 inside the stadium. At one of the ends of the arena there is a transformable tribune 6, behind which, and adjacent to it, the building of the grandstand 3, there is a warehouse 7 of large-sized blocks 8 (Figs. 4, 10) for transforming the arena 1 with an opening 9 between the top of the building 3 and the bottom of the floor. The coverage of the stadium (Figs. 3, 4, 5) consists of the main longitudinal 10 and transverse 11 load-bearing structures with the upper belts of the same plane, in which the stationary parts 12 of the coating are supported by adjacent longitudinal 10, transverse 11 structures and buildings of 3 tier stands. Sliding blocks 13 of the coating with supports in the form of rollers with gearboxes, motors and a control system are based on rail tracks 14 of the upper belts of the transverse 11 load-bearing structures and are moved along them in the transverse direction to the extreme position in which they rest on the longitudinal stationary parts of the coating 12, bearing structures 10 and buildings of longline stands 3. Sliding blocks 13 are lattice, for example, in the form of standard rod systems of the Kislovodsk type.

In the coating over the arena, lower crane trusses 15 are installed on the lower belts of the transverse structures 11 with 16 ways to move the suspended crane beams 17. Crane trusses 15 extend over the transformed tribune 6 and, leaning on racks 18 on the building of longline tribunes 3, cover the warehouse 7 with support on construction of the back of the warehouse. Crane trusses serve as a supporting structure for this part of the cover 12.

Longitudinal 10, transverse 11 load-bearing structures and crane trusses 15 are made in the form of paired lattice structures with round pipe rods, which, in addition to the above, allows to simplify the suspension of crane beams 17 and the placement of rail tracks 14. We accept the transverse structures 11 and crane trusses 15 in continuous design, which improves their static performance.

The buildings of the long stands 3 and the corner buildings 2 on the walls facing the inside of the stadium have alternating in height 19 main and intermediate 20 floors with consoles (6, 7), on which rows of seats 21 with fences 22 are installed. From the main floors 19 viewers fall on intermediate floors 20 through flights of stairs 23.

The transformation of the arena 1 consists in installing on it with crane beams 17 large-sized blocks 8, which completely cover it (Figs. 8, 10). Blocks 8 ultimately form either a horizontal floor 24, or a spectator stall with rows of seats 25 and longitudinal and transverse passages 26, or a combination thereof.

The longitudinal bearing structures of the coating 10 mate with the frame of the corner buildings 2 (Fig. 9) having vertical columns 27, floors 28 and diagonal connections 29. A single spatial structure is obtained in which the corner buildings 2 are connected not only by the buildings of the long stands 3, but also in longitudinal direction by conventional frames, the struts of which are parts of the frames of these buildings, and with the crossbars - longitudinal structures of the coating 10.

In the transverse direction of the stadium, the corner buildings are also connected in the plane of coverage by the supporting transverse structures 11. To improve the operation of such a frame, struts 30 are introduced at the interface between the crossbar and the strut.

Indoor stadium operates as follows. In the cold season and bad weather (rain, etc.), the translucent coating is closed and protects participants in events and spectators. The necessary temperature and humidity conditions inside the stadium are provided by modern engineering systems (heating, ventilation, air conditioning, etc.). In favorable weather, the coating blocks 13 are moved apart to insulate the internal volume and the arena.

Spectators fill the ordinary stands of 4 stadiums according to the standard scheme through loading hatches. Spectators enter the tiered stands of 5 corner buildings 2 and buildings 3 as follows: to the nearest main floor (floor 19), the lift is carried out along the general vertical communications of the buildings - stairs, elevators, escalators (not shown conditionally in the drawings) and then go to their place at the main ceiling 19 or intermediate 20 through the stairs 23. The evacuation of the audience occurs in the reverse order.

The transformation of the stadium depends on the event. For example, after a football match, a concert will be held at the stadium. In this case, it is necessary to equip the stage and the audience in the arena. The installation of blocks with seats 25 is carried out by the operators of the crane beams 17 and close each area of the arena with a width of a quarter with four cranes, as in the example in the drawings. The installation of blocks 25 starts from the farthest from the warehouse 7 and then all the others are mounted sequentially “on themselves”. Before installing the unit on the grass arena, the worker first removes grass pallets from it at the locations of the block supports.

Let us determine the installation time of the blocks on the arena with its dimensions 125 * 80 m (field 105 * 68 m plus zones to the stands), the dimensions of block 8 in terms of 12 * 10 m, the speed of lifting and moving cargo 20 m / min, lowering 5 m / min . With these sizes, the crane lifts the block from the warehouse to a height of 40 m (we believe that the crane takes the blocks from the bottom of the warehouse), moves it to 185 m and lowers by 60 m. Combining the movement and lowering of the load, we obtain the installation time of the farthest block:

T = (40/20) + (60/5) = 2 + 12 = 14 min.

The length and width of the arena are set accordingly,

P _dl = (125-6) / 12 = 10 pcs., P _w = 80/10 = 8 pcs.,

therefore, each crane must set 10 * 2 = 20 pcs. and then the installation time of all 80 pcs. blocks with four crane beams 20 * 14 = 280 min. or 280/60 = 4.7 hours. Adding 1.3 hours to sling, return cranes, etc., we get the arena transformation time - 6 hours.

After mounting the blocks, the platform 6 is flipped and the stage is formed, the scenery, curtains, etc. are suspended. The transformed tribune-scene 6 can be solid or consist of blocks depending on the parameters of the scene. The 6 rooms of the building of 3 tier stands adjacent to the stage 6 are used as dressing rooms, artistic rooms, etc. Arena retransformation is performed in the reverse order.

The main advantage of the proposed solution of the indoor stadium is the implementation of a single functional concept, which provides not only a clear separation of the functions of the main elements, but also their close relationship and combination of functions. This approach and its constructive implementation allow:

1) at the expense of longline stands to improve the conditions of visibility and the presence of spectators on them;

2) to ensure not only the quick transformation of the stadium for any spectacular events, but also expand the capabilities of the structure in this regard thanks to overhead lifting and transport equipment;

3) get a logically simple and clear design that meets the basic principles of designing reliable and economical systems.

All this leads to an improvement in the technical and economic indicators of the system and allows to reduce the building area (by about 8-10%), reduce the specific consumption of materials (15-20%), the cost of construction (20-25%) and, especially, the operation of the structure.

Claims (4)

1. An indoor stadium with a rectangular arena, four buildings at its corners, ordinary stands on the long and short sides of the arena between corner buildings with the excess of the first row above the arena, two longitudinal bearing structures of the coating with a stationary part above the ordinary stands and a sliding translucent part above the arena, characterized in that along the perimeter of the stadium between the corners there are buildings with ordinary stands below and cantilevered stands above them, and the cantilevered stands in height also have an angle building on its sides inside the stadium, in one of the ends of the arena there is a transformed tribune, the building of tiered stands with an aperture to the bottom of the cover, a warehouse of blocks for transforming the arena, and the cover consists of the main longitudinal and transverse load-bearing structures with upper belts of the same plane, stationary parts coatings are based on adjacent longitudinal, transverse structures and buildings of longline stands and serve as supports for sliding blocks of the coating when it is opened, while in the coating above the arena on the lower belts of the main transverse structures installed longitudinal crane trusses with the ways to move the suspended crane beams, which extend over the transformed stand and, resting on racks on the longline stands, overlap the warehouse with support on the construction of the back of the warehouse, being also the supporting structures of the stationary coating of this part of the stadium, and the crane - girders, providing work across the entire width of the arena, go to the warehouse and back into the openings between the top of the tier stands, the bottom of the cover, the walls of corner buildings and the stands of crane farms In the coating, the main longitudinal bearing structures mate with the frame of the corresponding corner buildings, forming a single structure with them, and the arena transformation blocks are large-sized rectangular structures with a supporting lattice frame and four corner supports at the bottom in the form of racks, some of which are on top rows of seats with seats, and other blocks - a horizontal floor, which, depending on the events held, are installed in a certain place of the arena by crane beams, closing the entire arena, while To install the block supports on the supporting base of the grass arena, pallets with grass are previously removed from it. 2. The indoor stadium according to claim 1, characterized in that the longitudinal, transverse load-bearing coating elements and crane trusses are made in the form of paired lattice structures with rods of round pipes. 3. The indoor stadium according to claim 1, characterized in that the transverse load-bearing coating elements and crane trusses operate according to a continuous structure. 4. The indoor stadium according to claim 1, characterized in that for the upheaval of the transformed rostrum and the formation of the stage, crane cover beams are used.

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