DE1291211B - Protective wall with devices for deflecting strong air currents - Google Patents

Description

The invention relates to a protective wall with devices for deflection strong air currents, especially when used at airports to deflect the exhaust gas flows of jet engines, with strips welded together, made up of several There are pairs of webs created by longitudinal cuts, the webs in opposite directions Directions perpendicular to the stripe plane are bent and between the web pairs Have lying patches of surface, which one below the other and to the patches of the other Stripes are parallel.

The invention is based on the object; a protective wall of the above Kind to develop with the jet engines among other uses -powerful and hot streams of exhaust gases emitted by jet planes are particularly effective are deflectable. This object is achieved in that the surface pieces are inclined to the wall plane and that the outer edges of one in the one direction and a web bent in the opposite direction with one another in the The apex line of the deflection are welded so that in the appropriate position The air or exhaust gas jets hitting the protective wall horizontally behind the wall are steep be distracted upwards.

The protective wall according to the invention ensures that behind there is practically no horizontal flow in the protective wall against which it flows, rather, the air or the exhaust gas experiences a steep upward deflection. The on protection for people behind the wall is achieved in this way extraordinary good. Here it must be regarded as particularly disadvantageous that the protective wall is very much in spite of the numerous openings arranged in it remains stable and offers a high resistance to deformation.

It has proven to be particularly advantageous if the sum of the The angles that the surface pieces occupy to the wall plane and this to the floor are larger is than 90 °. It is also recommended that the sum of the angles has a value that is smaller is than 130 °. Here, the angle of the wall plane to the floor is expediently 60 ° and the angle of the patches zVr. Wall plane preferably 35 to 45 °.

An embodiment of the invention is shown in the drawing. In it, F i g. 1 shows a side view of an element of the protective wall, FIG. 2 a plan view of this element, F i g. 3 shows a section through the element according to the line 3-3 of FIG. 2; F i g. 4 three of the ones shown in FIGS Elements, -F i g. 5 shows a section through the protective wall along line 5-5 of FIG G. 4, fig. 6 shows a protective wall in a lateral section, FIG. 7 is a front view the protective wall and its substructure and F i g. 8 is a plan view of this protective wall and its substructure.

The protective wall consists of metallic, strip-shaped elements 1 made of sheet metal, flat iron or steel strip of a certain width and length (FIGS. 1 to 3). The protective wall has windows 2 at regular intervals, which preferably lie on a center line of the sheet metal and are formed from straight longitudinal slots AB. All longitudinal slots, e.g. B. A1 Bi, lie on the same center line as the longitudinal slots AB, but are separated from these by patches 3 of the same length, z. B. AB ,, BA2 ETC.

A longitudinal slot is bordered by two strips 4 and 5. To produce an element 1, the strips are bulged in opposite directions perpendicular to the plane of the sheet. Thus, for example, the strip 4 protrudes in one direction and the strip 5 in the other direction with the same shape from the sheet metal plane of FIG. 2 out. These projecting parts can be in the form of folded strips with edges 4 a and 5 a , as shown in FIG. 1 shows. The shape can also be more or less rounded, or the edges 4 a and 5 a can be replaced by small flat pieces. The in FIG. The window 2 shown in FIG. 3, which is designed in the shape of a rhombus, can thus have a shape that differs somewhat from a geometric rhombus shape. The flat pieces 3, which separate the longitudinal slots, lie in the plane of the sheet.

The contour of the diamond-shaped window 2 is shown in FIG. 2 to one Line A-B degenerates, i.e. This means that the contour that lies in the plane of the sheet is in the longitudinal direction and aligned perpendicular to the plane of the sheet.

If you have such an element z. B. places on a horizontal plane, on the one hand the vertices 6 of the rhombuses and on the other hand the edges C -D, E -F are in contact with the horizontal planes.

There is therefore a relative inclination of the band-shaped elements 1 to the horizontal plane on which they rest.

If you have identical elements on the same level, e.g. For example, the members 1A, 1B, 1 C (F i g. 4 and 5) sets, as are the flat surface pieces 3 of the same in parallel, with each other, the elements are provided only at the Punkien 7 in contact, the point 7a of the element 1 A or point 7 b of element 1B (FIG. 2). The protective wall is created in that several elements 1 are welded together at points 7. In this way, a protective wall is obtained which consists of band-shaped elements, the surface pieces of which lying in the plane of the sheet metal are all inclined at the same angle relative to the planes XX-YY. The protective wall can be welded to rails or a plate 8, or it can also be designed as a simple association of various elements 1A-1B-1C etc.

Despite the large dimensions of the windows 2 and the openings 9 between the surface pieces 3, the protective wall has a very high strength.

F i g. 6 shows the protective wall when used on an airfield as a protective device against the exhaust gas flows from engines J. These flows have a direction according to the arrow f l.

The height of the protective wall is such that the passengers and the staff be protected from the exhaust gas flows. In the majority of cases, one height is sufficient from 1.50 m, measured from the ground. Of course, however, this level of Height of the engines to be adapted to the aircraft.

The barrier is inclined at the angle b from the horizontal, in such a way that it drops in the direction of arrow 1l. This angle is approximately 60 °. The inclination of the elements relative to the plane of the barrier can be within certain Limits can be varied. An angle of approximately 40 ° can be realized particularly easily will. Then the inclination of the surface pieces 3 is approximately 100 ° relative to the horizontal Exhaust gas flow direction.

It follows that the flow flowing horizontally on the deflectors impinges and passes through the windows 2 and C openings 9, according to the top the arrows 12 is deflected.

As experience shows, in this way one gets a perfect one Protection even if the engine is at a distance of 15 m from the protective wall is located. In this case, too, the flow becomes almost completely steep deflected above.

The angles can be varied as required. However, it is necessary that @ the total angle a + b is greater than 90 °. If the angle is just a little bigger than 90 °, the deflection upwards is very bad; the protective wall works then like a wall, and very strong dynamic pressure is exerted on it. is the angle, on the other hand, is very large, so the current still has after its passage a large horizontal component, and the protective wall only fulfills its function very imperfect.

In practice, the angle values that give satisfactory results deliver, between 98 and 120 °. The entire protective wall consists of a suitable one Number of part-walls arranged horizontally next to one another, of which each part-wall a protective wall P1 is P2 (Fig. 7) of the type described above; every partial wall can for example have a height of about 1.50 m and a width of about 1.20 m, wherein each band-shaped element 1 z. B. can have three diamond-shaped openings, where the distance between parallel, successive elements 1 is about 70 can be mm.

The adjoining partial walls are covered by iron plates Ml (F i G. 7 and 8) connected, and the outer edges of the barrier are on U-irons M2, M3 attached, which in turn are welded with their lower ends to U-irons M4, Mri, M, welded are. The latter rest on the floor or on any suitable support, e.g. B. made of concrete. They are on the ground or on this base by means of anchoring bolts Ni to N4 (Fig. 6) attached.

Claims (4)

Claims: 1. Protective wall with devices for deflecting strong Air currents, especially when used at airports to deflect the exhaust gas flows of jet engines, with strips welded together, made up of several There are pairs of webs created by longitudinal cuts, the webs in opposite directions Directions perpendicular to the stripe plane are bent and between the web pairs Have lying patches of area, which among each other and to the patches of the other strips are parallel, characterized in that the surface pieces (3) lie obliquely to the wall plane and that the outer edges of one in one direction and a web bent in the opposite direction with one another the apex of the deflection are welded, so that in the appropriate position Air or exhaust gas jets hitting the protective wall horizontally behind the wall be deflected steeply upwards. 2. Protective wall according to claim 1, characterized in that that the sum (a + b) of the angles, which the surface pieces to the wall plane and this to the Occupy the ground, greater than 90 °. 3. Protective wall according to claim 1 and 2, characterized characterized in that the angle sum (a + 6) has a value which is smaller than 130 °. 4. Protective wall according to claim 1 and 2, characterized in that the angle (b) the wall plane to the floor about 60 ° and the angle (a) of the surface pieces to the wall plane about 35 to 45 °.