SE423560B - AIRCRAFT HALL - Google Patents

Description

~ l5 20 25 30 35 40 _7ao14s2-6 D ~ 2 When using the new hall construction, the air which is to create the load-bearing internal overpressure is normally fed between the two layers. The air supply should be as even as possible. Due to the overpressure in the space between the layers, the air is passed through the inner air-permeable layer, whereby an overpressure is produced 'inside the hall, which is slightly lower than the overpressure in the space.

During the passage through the space and through the inner layer, the passing air will normally be heated by the heat which is carried out through the structure via transmission - mainly duct and radiation - from the heated interior of the hall. The velocity of the air and the air permeability and thickness of the inner layer must be adjusted in such a way that supplied feed air is normally heated sufficiently before it enters the hall. The amount of air supplied shall correspond to the total amount of air of the hall's leakage air and ventilation air. g - - Since heat transmitted through the inner layer is substantially returned to the hall through the supply air, the layer transmission losses should be almost completely eliminated. The heat is now used to heat the necessary ventilation and overpressure air.

It has been found that the new construction thereby gives a purpose ~. worth energy savings compared to known halls of double-decker construction. g * D g g When using the new construction, no problems arise with condensation against the outer, normally cold layer, as the air between the layers is obtained directly from the outside.

A construction designed according to the invention, which has low heat transmission, comprises an outer layer, which is normally relatively cold. Due to this, snow can accumulate on this layer and cause problems, unless it is removed. According to the invention, however, the new hall can also be designed in such a way that the temperature of the air which is fed between the two layers becomes controllable. By increasing the temperature of the supply air, it must be possible to heat the outer layer temporarily, so that the snow accumulated thereon is caused to melt.

With strong_solar radiation, conventional plastic halls heat up unacceptably much due to the solar heat. In this case, a significantly higher temperature can be obtained inside the hall than outside. A s.k. greenhouse effect arises. However, according to the invention, the new hall can also be designed in such a way that the air supply during sunny, hot days will take place directly into the interior of the hall, ie inside the inner layer. The supply air then has an outdoor air temperature. Due to the internal overpressure occurring in the hall, the hall air in this case is forced outwards first through the inner layer to the space and then further outwards, for example via valves or through leakage through the outer layer. The air heated by the solar radiation between the layers is thus discharged to the atmosphere and the temperature can in this way also be kept down both between the layers and on the inner layer, which of course also favorably affects the temperature inside the hall. No special cooling of the hall is normally required, but possibly the supply air may have a cold.

The invention is described in more detail below in the form of a couple of exemplary embodiments with reference to the accompanying drawings.

Figure 1 shows a cross-sectional view from the side of an airborne hall designed according to the invention, which is provided with double outer layers.

Figure 2 shows in perspective and in cross-section another design of an air-borne and double-outer hall, which is designed according to the principles of the invention.

The construction illustrated in Figure 1 comprises spaced apart cloths 10, 12, the lower edges of which are attached to a pre-arranged foundation 14. The inner cloth 10 is more air permeable than the outer one and the distance between the two cloths 10, 12 are controlled by means of spacers 16 in the form of rods, which may be articulated or telescopically shaped. This also simplifies both assembly and disassembly of the hall.

The reference numeral 18 denotes an aeration valve, which makes it possible to control the pressure inside the hall and / or in the space between the two layers 10, 12. Several valves 18 can be included in the construction and each valve consists of a pipe provided with suitable flow openings, preferably of plastic. The size of the flow openings 20 must be adjustable, so that the desired ventilation can be obtained.

In the embodiment shown in Figure 1, three supply pipes 22 for air are illustrated. The pipe ends are provided with guide dampers 24, so that the air can be fed directly into the hall and / or between the layers 10, 12 as desired. According to the figure, arrows show how air is forced through the inner layer 10 and into the hall. To provide the feed, fans (not shown) are used, which can provide the feed directly from the atmosphere or via temperature control units (not shown). At the edges facing the ground, the two layers can be joined together, for example welded together, thereby eliminating unnecessary air leakage. In the modified embodiment of the invention shown in Figure 2, the outer layer 26 is formed of a conventional plastic sheet, while the inner and more air-permeable layer consists of a support net 28 with air-permeable heat insulating arranged thereon. material such as glass wool 30. The layers are attached in this case with the lower edges against an annular foundation 32 and also in this embodiment spacers 34 in the form of rods are used, which are arranged between the two layers. It is also conceivable to use a special support structure which supports the inner layer, whereby the spacers can be eliminated. Air is fed through the wall construction at 36 normally to the space between the layers. A heat control unit 38 is located inside the hall itself. The heat control unit 38 normally heats the indoor air by circulating it. If necessary, supplied air can be heated by the assembly 38 before it is passed on via a supply means 40 in the form of one or more pipelines to perforated hoses 42 present in the space between the layers. By using these perforated hoses 42 it becomes possible to obtain a very even distribution of the supply air over the entire construction. Also in the embodiment according to Figure 2, there are adjustable valves 44 (only one is shown), which makes it possible to control the pressure both inside the hall itself and between the two layers.

With a suitable design of the inner layer and the air velocity adapted thereby, it is excellent to be able to feed air directly from outside to the space between the cloths. Instead of the above-mentioned rods 34, which form spacers between the layers, it is also possible to use ropes or the like. Other modifications of the described hall construction can also be made within the scope of the appended claims. _

Claims (6)

5 7801482-6 PATENT REQUIREMENTS 1. 1. An airborne hall comprising at least two layers spaced apart from each other (ID; 28, 30 and 12; 26, respectively) and arranged to be supported at least in part by an overpressure which is produced and maintained by means of feeding means (eg 22), which controllably supply air inside the inner layer (10; 28, 30), which is more air-permeable than the outer layer (12; 26), and / or between the inner and the outer layer, k characterized in that the inner layer (10; 28, 30) is arranged to be supported by the outer layer (12; 26) via support elements (16; 34). Hall according to claim 1, characterized in that the support elements consist of rods or ropes (l6; 34). Hall according to Claim 1 or 2, characterized in that the length of the support elements (16; 34) between the inner and the outer layer (10; 28, 30 and 12; 26, respectively) is adjustable. Hall according to one of Claims 1 to 3, characterized in that an air temperature control unit (38) is provided for heating the supply air of the supply means to the desired temperature. Hall according to claim 4, characterized in that the feeding means comprise at least one perforated hose (42), which is arranged between the outer and the inner layer (26 and 28, 30, respectively). Hall according to one of Claims 1 to 5, characterized in that the inner layer consists of, on the basis of a support net (28), air-permeable heat-insulating material (30) supported. ANFURDA PUBLICATIONS: Sweden 371 852 (EÛ4B 1/345), 393 142 (EO4B 1/345), 413 920 (EÛ4B 1/345), 419 459 (E04B 1/347) Finland 47 410 (E04B 1/345)