HU194354B - Building - Google Patents

Abstract

BACKGROUND OF THE INVENTION The present invention relates to a building having a base body, a lower and upper frame, and a metal structure, preferably an aluminum frame, a roof, a lateral space barrier, and a vent holes in the region of the lower and upper frame, and, where applicable, a sealing grid, in the region of the base. . The essence of the building is that the upper frame (8) consists of a frame profile (24) with a sloping outer wall (25) facing the inside of the building and a slanted outer wall (25) and inward plates (29, 30) over which from the inside, a concave curved flange profile (22) is provided, and the roof flange profile (22) forms an air flow channel (87) with the upper frame profile (24). -1-

Description

The invention relates to a building having a basic body. the lower and upper east, and the columns connecting them, have a skeletal structure, a roof, a lateral deflection barrier and a vent grille in the lower and upper frame region, preferably of aluminum, preferably retarded in aluminum. Examples of such buildings are flammable materials, explosive materials. chemical storage, air-conditioned small buildings in tropical areas and transformer houses, and other equipment such as they can be used for housing electrical switchgear, high power pumps and the like, which are very hot during operation. One of the functions of these buildings is to safely isolate the materials or products coming from them from the environment, and to remove the amount of heat generated by venting the confined space, and to protect the environment from possible explosion (flamethrowing) in the building. The building should also be protected against adverse environmental influences (rain, dust, snow, vandalism, splashing, etc.).

The designer's ambition worldwide is to construct the above-mentioned buildings with minimal space requirements, all the more so as they are often built in crowded urban environments. However, in most cases small buildings need to be ventilated artificially (mechanical), which is hardly permissible due to noisy operation in populated areas and on the other hand it requires considerable energy and supervision. Gravity ventilation of large interior buildings can be solved, but they have other drawbacks besides large space requirements: effective gravity ventilation requires the construction of buildings of a height greater than that required by technology, because this is the only way to ensure the necessary intensity of the thermosiphon flow; the availability of buildings of aesthetically pleasing standards is highly questionable; ventilation openings covered with a grille or gill can only be made so difficult that unauthorized persons cannot dirty the inside of the house, for example, children cannot put wire in the house; the roof structure must be insulated, etc.

To overcome these drawbacks, the solution described in Hungarian Patent Application No. 181,373, which has a small space requirement and has a covering liner and is ventilated by a maze-like ventilation between the base body and the lower frame, and the roof structure and the upper frame. . This solution involves partially folding the frame elements individually from aluminum sheet, or some of them, which entails high manufacturing costs, and from aluminum rectangular profiles, which means that a larger proportion of material is required than the statically necessary one, so it is inexpensive the proportion of material is relatively high. Another problem is that the labyrinth-like ventilation apertures are protective. placement of grids is elusively unsatisfactory because there is not enough space for this. Flow cross-sectional dampers are recommended to be installed in the vents, both top and bottom, but they are difficult to operate and are not always available to the operator.

SUMMARY OF THE INVENTION The object of the present invention is to provide a building of the type described above which satisfies the static requirements with a minimum specific material input, yet has optimum air flow cross-sections and allows the protection grilles to be installed in the vents without difficulty and eliminates airflow. the need for regulation.

The invention is based on the discovery that by using light metal, primarily aluminum, target profiles for assembling the frame structure, the construction of the building can be accomplished faster and more economically than before, and secondly, by satisfying the strength requirements by simply choosing the cross-sectional shape. conditions can be created that eliminate the need for artificial aeration structures, cutting, or even the installation of dampers, and there is ample space to install the grilles in the most favorable position.

Based on these findings, the object of the present invention has been solved by the use of a building having a metal body, preferably made of aluminum, comprising a base, lower and upper frame, and columns connecting them, and air vents in the lower and upper frame regions. and, where appropriate, having guard rails to close them, the building being characterized by a top profile having a slanting outer barrier from below and facing inwardly to the interior of the building, with a concave curved roof panel profile viewed from the inside el, and this roof flange profile forms an air flow passage with the upper frame profile. Advantageously, the curved edge profile extends into the interior of the building, preferably horizontal; it has a downwardly-preferably vertical plate and an arcuate portion, preferably a circular portion, connecting them, and preferably an upwardly extending rib is connected to the inner end region of the inwardly extending plate. In this case, it is also advantageous if the lower end of the downwardly facing plate has inwardly facing, interlocking gripping ribs, and the lower end of the downwardly facing plate has a rounded watertight flange, and An L-shaped rib is secured. According to another advantageous feature of the invention, the downwardly extending sheet of the curved roof profile is spaced overlapping below the top of the frame profile.

Another embodiment of the building is characterized by having rectangular columns of rectangular shape, preferably rounded at one corner, with ribs extending perpendicular to the two adjacent sides. It is also desirable that the building has intermediate columns having a flat U-section and short columns perpendicular to the longitudinal rib and having flanges extending parallel to the long rib on both sides.

According to a further embodiment of the invention, the inner roof panel 21, which may be partially delimited to the flow channel, can be connected to the curved roof flange profile.

1943 has a remprofile having a slanting closure plate from the top down to the inside of the building, the upper end of which preferably extends horizontally outwards and the lower end of which is also preferably inwardly facing, e.g. ceiling! a support flange is connected and the upper flange fits into the upper inward slit of the curved roof profile. In this case, it is advantageous to have an impact shoulder in the upper inner end region of the upper flange for supporting the curved roof flange profile and a protective grille or sealing plate or air filter insert or the like from above to extend outwardly on the outside there is an intermediate longitudinal rib serving, furthermore, if the angle of the oblique closing plate to the horizontal is between 40 and 90.

According to another feature of the invention, a lower downwardly extending - preferably vertical - shorter outer sealing wall is connected to the outer oblique sealing wall of the frame profile, with a lower inwardly extending - preferably horizontal - plate which overlooks an intermediate inwardly extending plate. which extends inwardly over the lower plate by a distance; a rib extending upwardly from the inner end of the intermediate plate and a rib extending downwardly from the upper end region of the outer oblique sealing wall to support an auxiliary wall, the ribs being preferably in a common vertical plane and having an opening therebetween; the lower and intermediate plates, the outer oblique barrier wall, the intermediate plate and the ribs also form compartments that are open to one another and open to the inside of the building. In this case, it is advantageous if the outer oblique sealing wall is connected to the upper rib by a transition section forming a contact surface, and if the external oblique sealing wall has a horizontal angle of 30-60 °, preferably about 45 ° and from the outer end of the lower inwardly projecting plate. a downwardly protruding nose and also a downwardly extending rib from the inner end thereof, and a collision shoulder formed by thickening the profile at the intersection of the intermediate plate and the inclined barrier wall.

According to a further feature of the invention, the lower frame of the frame structure is formed by a frame profile which is identical with the profile of the upper frame but is rotated 180 ° in a vertical plane. It is also advantageous if the upper air flow passage has an increasing cross-section from the inside to the outside and if the lower protective grille and / or the upper protective grille are installed in a horizontal or substantially horizontal position.

Another embodiment of the building is characterized in that the roof has at least one flip-open lid which is connected to the roof profile by an interlocking delay-retractor. Preferably, the aperture delay-roof water sealing device is formed by a cylinder connected to the roof flange profile by a hinged connection and a longitudinally movable outer end also by a hinged rod connected to the lid having a piston having a through hole (s) secured thereto; the rod portion between the piston and the outer end of the cylinder is surrounded by a helical spring and has a resilient stop member inside the cylinder .__ __

A very advantageous embodiment is that the roof flange profile, together with the cover (s) attached thereto, is connected to the frame structure by means of a releasable connection, which is removable in one member. In this case, it is expedient to have one lifting eye in each of the four upper corners of the building, which also provides a releasable connection between the roof and the frame structure, and each lifting eye has an external threaded ring fixed to the roof flange profile; it has a concentric, laterally spaced, lower end with a threaded bore attached to the frame structure, and a stopper with a threaded fastening piece that can be folded into this threaded bore, and if the outside threaded ring has a threaded bore, and has a lifting member with a threaded shaft and containing a lifting ring.

The invention will now be described in more detail with reference to the accompanying drawings, which show an advantageous embodiment of the building and some details thereof. In the drawings, Figure 1 is a side view of the building, with part of the side cladding cracking out;

Figure 2 is a horizontal sectional view taken along the OC_ line of Figure 1, with partial removal of the floor panels;

Figure 3 is a vertical sectional view taken along the line E-E1 in Figure 2;

Figure 4 is an inside perspective view of a corner section of a building;

5-9. Figures 1 to 4 show preferred embodiments of the profiles used to form the frame structure of the building;

Figure 10 is a larger vertical sectional view taken along line B-B in Figure 1; however, the intermediate part of the structure, between the lower and upper frames, is not depicted in order to provide greater clarity;

all. Fig. 4A is a perspective view of a preferred embodiment of the roof;

12 in all. Fig. 4A is a perspective view of the opening delay-roof-closing device of Figs.

Figure 13 is a perspective perspective view of one of the lifting eyes, disassembled;

FIG. 14 is a view showing the structure of FIG. 13 with a lifting tab provided for lifting the roof;

Figure 15 illustrates the structure of Figure 13 with a lifting eye provided for lifting the entire housing.

As shown in FIGS. 1 to 8, the frame structure of the present invention, which is generally rectangular in plan, is represented by a reference frame 7, a top frame 8, a corner post 9 and an intermediate post 10. The building is bordered by 2 roofs, 11 floors below, the lower plane of which is at a distance of m above the floor (Figures 1 and 3). The base of the building, which in this example is a reinforced concrete beam frame, is designated by reference numeral 21. The side walls of the building are formed by side panels 3, preferably made of aluminum sheet, having a flat U-shaped cross-section (Fig. 2) and secured between the columns 9 and the intermediate columns 10 by their legs. In the present embodiment, the building has one single-door door and two 5, 6 double-leaf doors.

It has 194,354 doors which open outwards and which are also preferably made of aluminum. The roof 11 is made up of lids 12, which are capable of opening and closing, which communicate with the frame structure 1 by means of a tongue-and-drop roof closing device 14; we will return to a more detailed description of the latter later. As shown in Figures 2 and 3, along two longitudinal walls of the building, two openings 82 extend longitudinally apart from the base 21 in the area of the lower floor, which are covered by horizontal guard grids 19. Floor panels 13 are located at intervals m above the grilles 19. In the area of the patio, in the corners, diagonal stiffening profiles 20 are incorporated diagonally to accommodate the stresses occurring when the body is raised. A roof 16 is connected to the roof 2 in each of the four upper corners of the building; we will elaborate on this later. The interior of the building is divided into 17 spaces by 17 partitions; the partitions are also made up of 10 intermediate columns and 83 plates placed between them. Figure 1 is a detail of an auxiliary roof with reference numeral 15; we will return to that role later. Under the roof 2, an inner cross member 18 extends in the region above the right bulkhead 17, which is fixed to the upper frame 8 by its ends (welded) and additionally stiffens the frame structure. The frame structure 1 may also have lower cross members, which are, of course, fixed to the lower frame 7.

Figure 4 is a perspective view of a detail of the frame structure 1 from the inside of the building. This figure clearly shows the target profiles forming the frame structure, preferably made of aluminum.

The upper frame 8 is made using the frame profile 24, which is shown in larger scale in cross-section in Figure 5. The profile 24 has an outer oblique barrier wall 25, an outer vertical barrier wall 26 connected thereto, and the walls and inwardly projecting horizontal plates 29,30, as well as 31a. The inner vertical ribs 31b have chambers 27, 28 which open to the interior of the building. The plate 30 is joined by a flange 33 perpendicular to it at its free end, which is vertical when the profile 24 is mounted. At the opposite end of the plate 30, the plate 30 also has a nose 35 which protrudes from the plate perpendicularly thereto. Below the upper horizontal plate 30, a spacer shoulder 34 is formed in the inner end region of the intermediate horizontal plate 29 at intervals Tj (e.g., about half or slightly less than the height M), the plate 29 and the outer oblique 25 The inner ribs 31a, 31b in a common vertical plane face each other with a longitudinal opening 32 extending therebetween. E 31a. The vertical plane of the winches 31b extends from the inner end Tj of the plate 30, which may be equal to half or slightly less than the full profile width s. There is a transition section 36 between the rib 31b and the inclined wall 25, which has an external support surface. The above-described design of the frame profile 24 is not only functional advantageous but also the stiffness of the partially closed profile profile is such that it is able to withstand the stresses that occur. Its production capacity is good, the chamber 27 can be closed if necessary and the load capacity can advantageously be increased.

As shown in Fig. 10, the frame profile 24 is mounted as an upper frame 8 in the same position as in Fig. 5 and a lower frame 7 in a position rotated 180 ° in a vertical plane relative to Fig. 5. The angle ε of the outer oblique sealing wall 25 enclosed horizontally may range from 30 to 60 °, preferably 45 °. The height M of the profile 24 is e.g. 135 mm, wall thickness 2.5 mm; the size s is e.g. 115 mm, size ≤ 70 mm, size L 8 ~ mm, size J ≤ 20 mm.

6 is a cross-sectional sectional view of corner posts 9 having a cross-sectional shape (e.g. 80x80 mm) having two adjacent walls extending from adjacent ribs 39, 40, e.g. They may be 25 mm and spaced b apart from a corner point between them having a size greater than half the length of the walls 37, e.g. 52.5 mm. At the intersection of the walls without the ribs 37, the corner is curved; this rounded corner is designated 38. The profile also has a wall thickness of 2.55 mm. The ribs 39, 40, moreover, provide sufficient overlap to connect (support) the side wall panels 3.

As shown in Figure 7, the profile of the intermediate columns 10 is an open-section U-profile (hat profile), whose legs 42 are connected to the outer end of the legs by a flange 43 extending perpendicularly to the legs, i.e. parallel to the long rib 41. These flanges are also used to support the sidewall and partition panels. For wall profiles up to 2.5 mm thick, eg. 80mm, d size 35mm, e size 25mm.

In Figure 8, the curved roof profile of the roof, designated 22 in its entirety, is shown in larger cross-section. This profile has an inwardly extending plate 44, a downwardly extending plate 45, and an arcuate portion 46 connecting the two portions of the plate, preferably circular in shape; the radius of the circle is indicated by the reference letter R. When the profile 22 is installed, the plate 44 is horizontal and the plate 45 is vertical. On the inside surface of the downwardly projecting plate 45, facing the interior of the building, near the lower end of the plate, there are short inwardly extending gripping ribs 47, 48 with a slot 49 therebetween. The free lower end of the plate 45 is formed as a slightly widened rounded water-conducting flange. A vertically upwardly extending rib 51 is connected to the end of the inwardly extending plate 44, and at the bottom of the end of the plate 44 is an L-profile clamp 52 defining a slot 53 facing the interior of the building with the lower surface of the plate 44. In addition to the stiffening of the rib 51, it also has a watertight function with the downwardly extending rim 12a of the lid 12.

The profile _{has a} height of M _{t of} 22 profiles with a wall thickness of 2.5 mm, e.g. Note that the profile 22 of Figure 4 is slightly different from that described above, in that the upwardly extending flange 33 is not slightly at the inner end of the plate 44, but slightly outwardly from it. is connected to the disk.

Referring now to FIG. 9, the joint roof flange profile 23 is generally inclined with an oblique closing plate 54 having a horizontal upper flange 55, also a horizontal lower flange 56, a stop shoulder 57 formed in the region of the inner end of the flange 55 has a short intermediate rib 58 in its region. The angled δ angle of the oblique sealing plate 54 may be between 40 and 90 °, preferably about 60.

194 354

Figures 4 and 10 depict the profiles described above more schematically than those shown in Figures 5-9. 4 and 10 are only a portion of the reference numerals. Based on the latter figures, the functions of the building profiles and the openings formed or bounded by the profiles will be explained below. In the lower part of FIG. 10, the reference letter f denotes the width of the ventilation air inlet flap 85 between the inner sides of the profile 24 forming the lower frame 7 and the base 21. The opening 85 extends on two longitudinal sides of the building, in the present embodiment only in the central section between the two partitions 17 (Fig. 2), but in other embodiments it can be formed on all four sides, or even in full length. The inlet 85 is covered by a lower guard grid 19, which lies on a horizontal inwardly extending plate 29 of the profile 24.

The outer end of the lower guard 19 rests on the stop shoulder 34, but e.g. can also be fastened to the plate 29 using screws. The direction of flow of the incoming air is indicated by the arrow Aj, the flange 33 of the profile 24 serves here to support the lower end of the side wall panels 3 and, when properly overlapped, provides the necessary closure. For the edge ribs 33 or otherwise, e.g. The baffle plates 11 mounted on the cross-bracket control the air flow but also increase the protection against splashing.

The layout and function of the 8 upper frames of the building as well as the roof tiles are shown in both Fig. 4 and Fig. 10. 24 of the 8 upper frames

The above-mentioned curved roof ridge 22 and its associated roof ridge profile 23 form an air flow passage 87, the height of which is denoted by the reference letter d. The outer lower edge of the roof flange profile 22 extends downwardly g upwardly from the uppermost pillar of the profile 24, i.e. the upper plane of the transition section 36, which is all advantageous in terms of flow. The channel 87 is provided with a horizontal upper guard 81 which fits with its outer end into the slot 49 of the profile 22 (see also FIG. 8), with its inner end supported by the lower surface 58 of the intermediate longitudinal rib 58 of the profile 23. lie down (see

5). One of the great advantages of the design of the channel 87 according to the invention is precisely the possibility of the horizontal positioning of the guard grille 81, which effectively prevents the penetration of porn, dust contaminants on its surface, since it has a maximum resistance to upstream material. practically no obstacle to the flow of air from the inside to the outside. The portion 81a of the guard grille 81 between the gap 49 and the transition section 36 has a length D _x greater than the height dj of the channel 87 (FIG. 10), which is favorable for ventilation efficiency. The air outflow was indicated by reference numeral 86 and the air outflow from the building was detected by arrows A2. The exhaust air is effectively guided or deflected by the outer oblique barrier wall 25 of the profile 24. It will be appreciated that there is no unconditional need for the protective grille 81b (Fig. 10), in which case the vent grille 22 may be supported by a spacer in the horizontal plate 44 of the profile. Incidentally, the upper guard grille 81 is not shown in Figure 4, for the sake of clarity. The guard grille 81, which is provided by any grid structure, e.g. it can also be a perforated plate - it can have any permeability, ie, an opening-surface, or in some cases a solid air-sealing plate, instead of protective grilles, so that the desired level of protection can always be set or implemented. The same considerations apply to the lower guard grille 19, which may also be replaced by a solid plate. The guard grille can be replaced at any time on a solid plate or air scrubber pad and vice versa, so that the airflow conditions can be adapted to the new function whenever the function of the building is changed.

The water-conducting flange 50 of the profile 22, like the nose 35 of the profile, facilitates the drainage of rainwater. The horizontally inwardly extending lower lip 56 of the profile 23 fitting into the slit 53 of the profile 22 provides a support for the false ceiling 84 depicted in bold in Figure 10. The abutment shoulder 57 of the profile 23 serves to support the inner end 22; the upwardly extending rib 51 is externally closed by the downwardly extending rim 12a of the lid 12. In the chamber 27 of the profile 24 forming the upper frame 8, the chamber 27 of the profile 24, shown in bold in Figure 10, extends through the opening 32 with the auxiliary lid 88 shown in Figure 10, the end of which rests on the inner rib 31a. This inner cover is used for rain, dust, etc. provides extra security against entering the building; temporarily covers the inside of the roof when lifting the roof structure, directs or prevents condensation; if inside the building, for example, arcing short-circuiting, internal separation; and finally, to exclude flow-undesirable internal components from the main air flow path.

The protruding ribs 39, 40 of the corner posts 9 of FIG. 6, as shown in FIGS. 2 and 4, serve to support or connect the side wall panels 3 in the same manner as FIGS. The edges 43 of the intermediate columns 10A to FIG. The outer corner of the column 9 is rounded for aesthetic reasons (Fig. 6).

Given that the building is primarily intended to accommodate explosive and / or flammable equipment and / or materials, an embodiment of the roof 2 has been designed to open automatically upon explosion and then automatically reclosure upon loss of overpressure. The building shown in Figure 1 also has such roofs. Figures 11 and 12 illustrate in greater detail such a roof structure having two lid portions 12, one of which in an opening configuration has a strap attached to the roof flange profile at one of its edges. In Fig. 11, the structural elements already described are denoted by the reference numerals already used. A rod 60 is hinged to the hinged lid 12 with a pivot link 62, and a cylinder 59 is hinged to the roof flange profile 22 and the hinged rib connecting thereto. Taken together, these components form the aperture-delay-roof-sealing structure, designated throughout with reference numeral 14. The rod 60 in the cylinder 59 can move in accordance with the double arrow x. The inner structure of the 59Tienger is illustrated in Figure 12 with the rod 60 therein. At the inner end of the bar 60 there is a plunger 66 having a plurality of orifices 66b in its front face 66a, which is provided with a flexible disc 67 that fits closely to cylinder 59, preferably a plurality of flexible apertures 67b, preferably a rubber disc covers. The threaded end of rod 60 is secured to piston 66 and disc 67 by nut 68. The portion of the bar 60 between the upper end of the cylinder in the open position of the lid 12 and the piston 66 is partially or wholly surrounded by a helical spring 65. At the lower end of the cylinder 59 is a damping disk 69 made of a resilient material such as rubber. In order to secure the pivot connection 62 of the rod 60 (Fig. 11), the rod has an outer lug 64a with a hole 64a at its outer end; similarly, a tab 63 having such an opening 63a is fixed to the lower end of the cylinder 59, which is below the cylinder. 6A and 6b are designed to provide a hinged connection 61.

When an explosion occurs inside the building, the overpressure, as indicated by arrow K in FIG. 11, opens the lid and causes the bar 60 to slide out of the cylinder 59 in the direction of the opening shown in FIG. The power of the mill is - e.g. expected in the transformer housing - to know the explosion power. The structure 14 is only limited when opened, in which case the elastic disk 67 is lifted from the holes by the air flowing through the holes 66b, thereby providing free flow. When the result of the explosion - the overpressure - is eliminated, the 65 springs and / or the spring will be removed. the weight of the lid moves the rod 60 back into the cylinder 59 in the direction of the arrow N _{2 in} Fig. 12, that is, the lid 12 locks back into place. The recirculation in the holes 66b is only slightly attenuated by the return air (Fig. 12, arrows F), since this

In this case, the resilient disc 67 will adhere to the holes 66b, so that the explosion will practically not damage the roof structure and the building itself, and the lid 12 will be so gently - retarded after the phenomenon has occurred - the structure 14 and the roof 2 itself have no harmful consequences.

Thus, the roof structure of the above-described design functions as a safety valve and serves as a pressure relief function. Allows the building (spatial structure) to be lightweighted (otherwise the sides of the building would have to be dimensioned to absorb the full pressure wave), provide directional drainage of internal overpressure and combustion products (eg curved short circuit), property and personal protection. If an explosion is likely to occur in a part of the building and there is no special need for the air flow passage, the upper air flow passages 87 may be closed with a closed plate 81 to increase security.

13-15. Figures 1 to 5 show a preferred embodiment of the lifting eyes 16 located in the four upper corners of the building. The lifting eye 16 has a larger diameter outer threaded ring 71 which is welded to the roof flange profile 22 by its lower flange. The ring 71 has a concentrically smaller, outer-threaded lifting spindle 72 which has a threaded hole 72 and is welded at its lower end to a locking plate 70 covering the upper end of the corner post. There is a distance p between the inner surface of the ring 71 and the outer surface of the spindle 72.

The closure cap 73 of Fig. 13 can be zipped externally with a threaded fastener 74 which can be inserted into the threaded opening 72a of the spindle 72. Usually, this is the shape of the lifting eye assembled (Figures 1, 2, 4, 10 and 12). By screwing the sealing caps 73 onto the rings 71, a solid, soluble connection is formed between the roof structure 2 and the building frame structure 1 (of which the corner posts 9 are naturally part) and the sealing caps protect against the rain and underneath them. rings and lifting spindles 72. If the roof 2 is to be lifted out of the building, the cap 73 is removed from the ring 71, thereby releasing the roof 2 from the corner post 9 and fitting the inside threaded sleeve 75 of Figure 14 onto the outside threaded ring 71. With the lifting lugs 76a having an opening 76a - of course the four lifting lugs in the four upper corners of the building - the roof structure, e.g. can be lifted by a crane using a crane.

If the entire building is to be lifted in a single member, after removing the cap 73, the lifting member 77 of FIG. 15 is driven into the threaded bore 72a of the lifting spindle 72 by its threaded stem 80, which has a stopper 79 and above a lifting ring 78. By hooking the crane hooks to the 78 lifting rings of the four lifting eyes 16, the building can be lifted in one member.

The nodes of the geometrical structure - body - formed by the wrapping of vertical or horizontal planes defined by the linear aluminum profiles according to the invention are preferably stiffened by welded joints, and the joints and angles of the joints are precisely secured and oriented to the desired angle. appropriately. The linear profiles can be connected to each other in a girth, which is suitably formed to form a spatial geometry of column geometry, in combination with a 90 ° locking node that combines three or three planes, in combination with a corner node, which also protects against twisting. The enclosed corner posts 9 can be welded to the frame profiles 24 either externally or internally.

Advantageous effects of the invention include:

The frame structure can be assembled from only three special profiles and can be transformed into one or two additional roof flange profiles that require only external sheathing. The length of the profiles can be practically arbitrary, so the frame structure can be improved towards my space. The half and bottom frames of the frame structure are preferably made of the same profile but, due to their position, perform different functions when using the building. The lower frame provides transport protection during loading, secures it to the base, the profile - due to its special cross-sectional shape - receives the lower cross members, hides the lower ventilation grids, solves the lower waterproofing of the casing elements and keeps the lower pivot of the doors. The upper frame, together with the curved roof bracket, provides ventilation; the aquatic beard solves the drainage of rainwater; it receives the upper cross members, covers the panels (side panels), and serves as the upper holder for the door frames. In addition, it allows the roof to be lifted in one member (secured to it with a detachable connection) and thus facilitates installation work inside the building. The closed profile columns connecting the upper and lower frames in the corners may or may not fit into the frame profiles. The cavities formed in the linear profiles, which are also suitable for connection to other profiles, eliminate the need for welding templates and allow the assembly of the linear profiles delimiting the spatial structure at the required angle. This is also a very advantageous factor in manufacturing technology. The lifting eyes according to the invention a

194,354 provides the possibility of removable attachment of the roof to the frame structure, lifting the roof off the building and lifting the building (including the roof) in one member. Roof lifting points shall only be accessible when the roof is not connected to the rest of the space structure; this is a very beneficial factor from a security point of view. The frame structure is raster-reinforced by the intermediate columns connecting the lower and upper frames, while also providing a functional, formal articulation of the spatial structure. The framed column profiles form closed plane frames to fit the sidewall panels, with overlapping connections required by the environmental eye. Otherwise, the use of intermediate columns is not always necessary, in the case of simpler load cases or in the case of lower columns. for smaller building sizes, their static role can be taken over by sidewall panels. A roof slab that opens due to internal overpressure will cause an explosion in the building, arc effects (arc blasting, etc.). it protects the building from the harmful effects of overpressure and protects the environment and persons near the building from the effects of the explosion. The roof panel is retracted retarded after the overpressure has ceased, thus again covering the space structure continuously.

The load-bearing capacity, structural strength and weight ratio of the building according to the invention are significantly better than such parameters of currently known structures, but due to the optimal flow cross sections, gravity ventilation, protection against environmental influences, internal overpressure, and the variability of the extent, magnitude, and amount of these favorable functional properties throughout the bounded space. It is not necessary to install dampers to control the air flow. By choosing the cross-sections, positions and surfaces of the profiles and the ventilation grilles, the ventilation optimum can be set once and for all when assembling the building, according to the demand side,

The building according to the invention is widely applicable, particularly advantageous in the form of surface spray protection, for storing flammable, explosive and chemical materials and for placing technical equipment therefor; for the construction of transformer stations, pump houses and the like, generally for the construction of pump houses and the like, generally for spaces in which highly heated machinery, equipment, etc. are built-in; and finally as air-conditioned small buildings in tropical climates.

The invention is, of course, not limited to the embodiment detailed above, but may be practiced in many ways within the scope of the claims.

Claims (25)

Claims 1. A building having a base body, a lower and upper frame, and a metal frame, preferably made of aluminum, comprising columns connecting them, and a lateral enclosure, and ventilation openings in the region of the lower and upper frames, and, where appropriate, protective grilles characterized in that the upper frame (8) is lined with a frame profile (24) having a slanting outer sealing wall (25) from below upwards and towards the interior of the building, and inwardly facing plates (29, 30), above which a curved roof edge a profile (22) is provided, and the roof flange profile (22) forms an air flow passage (87) with the upper frame profile (24). (Figures 4 and 10) (1st, 25th June 1986) Building according to claim 1, characterized in that the sheet (44) of the curved roof flange profile (22) extends towards the interior of the building, preferably horizontal; having a downwardly-preferably vertical plate (45) and an arcuate, preferably circular, portion (46) connecting them, and an upwardly extending rib (51) for the inner end region of the inwardly extending plate (44), preferably at the very end of the plate (44). join. (Fig. 8) (El. 25, 1986) Building according to Claim 2, characterized in that, in the region of the lower end of the downwardly projecting plate (44), there are inwardly facing slots (48, 49) forming a gap (49) (Fig. 8). 25.) Building according to claim 2 or 3, characterized in that the lower end of the downwardly extending plate (50) has a rounded water-conducting flange. (Figure 8) (El. 25.11.1986) 5. A building according to any one of claims 1 to 6, characterized in that an L-shaped rib (52) defining an inwardly facing slot (53) is fixed in the region of the inner end of the top plate (44). (Fig. 8) (El. 25, 1986) Building according to one of Claims 1 to 5, characterized in that the downwardly extending plate of the curved roof flange profile (22) is spaced (g) below the upper point of the frame profile (27). (Fig. 10) (El. 25, 1986) 7. A building according to any one of claims 1 to 3, characterized in that it has closed rectangular columns (9), preferably rounded at one corner, and extending from two adjacent sides perpendicular to the booms (39, 40). (Fig. 6) (El. 25, 1986) 8. A building according to any one of claims 1 to 3, characterized in that there are intermediate columns (10) with flat U-sections, short ribs (42) perpendicular to the longitudinal side of the long rib (41) extending parallel to the long rib (41). (Figure 7). (Els. 1986). II. 25.) 9. Figures 1-8. A building according to any one of claims 1 to 5, characterized in that it has an inner roof flange profile (23) for partially defining the flow channel (87), which can be connected to the curved roof flange profile (22). ) having an upper end flange (55) extending outwardly, preferably horizontally, and at the lower end also. a ledge (56) for supporting the suspended ceiling (84) is connected, and the upper Eiborda (55) fits into the upper view slot (53) of the curved roof flange profile (22). (Figures 9, 8 and 10) (El. November 25, 1986) Building according to claim 9, characterized in that in the region of the upper inner end of the upper flange (55) - the curved roof flange profile 194.354 {22) - an abutment shoulder (57) and an intermediate longitudinal rib (58) extending outwardly on the outer side for supporting a guard grille (81) or an air filter insert or the like near the lower end of the oblique closing liner (54). ). (Figure 9) (Els, 25 June 1986) The building according to claim 9 or 10, characterized in that the angle (s) horizontally enclosed by the oblique sealing plate (54) is between 40 and 90 ° (Fig. 9). Building according to claims 1 to 11, characterized in that a shorter outer end wall (26) extending downwardly, preferably vertically, from the lower end to the lower end of the frame profile (24) is preferably connected. horizontal - a plate (30) extending above which an intermediate inward extension extends at a distance (Tj) - also preferably a horizontal plate (29) extending inwardly from the lower plate (30) at a distance (T ₂ ); a rib (31a) extending upwardly from the inner end of the intermediate plate (29) and a rib (31b) extending downwardly from the upper end region of the outer oblique sealing wall (25) to support an auxiliary wall (87), the ribs (31a, 31b) preferably in a common vertical plane with an opening (32) between them; the lower and intermediate plates (29,30), the exterior oblique sealing walls (25), the intermediate plate (29) and the ribs (31a, 31b) are also open to each other and open to the inside of the building (28,27). form. (Figures 5 and 10) (El. 25.11.1986) Building according to claim 12, characterized in that the outer oblique sealing wall (25) is connected to the upper rib (31b) by a transitional section (36) forming a contact surface. (Figures 5 and 10) (El. 25, 1986) Building according to Claim 12 or 13, characterized in that the angle (α) between the outer oblique sealing wall (25) and the horizontal is 30 to 60 °, preferably about 45 °. (Fig. 5) (El. 25, 1986) 15. A 12-14. A building according to any one of claims 1 to 5, characterized in that a nose (35) extending inwardly from the outer end of the lower inwardly extending plate (30) and also a rib (33) extending downwardly from its inner end (Fig. 5). (Els. 25, 1986) 16. A building according to any one of claims 1 to 5, characterized in that a stop shoulder (34) is formed at the intersection of the intermediate plate (29) and the inclined sealing wall (25) by thickening the profile (24). (Fig. 5) (El. 25, 1986) 17. A building according to claim 1, characterized in that the lower frame (7) of the frame structure (1) is formed by a frame profile (24) which is identical to the profile (24) of the upper frame (8) but rotated 180 ° in a 15 degree vertical plane. (5 and Figure 10) (El. 25, 1986) 18. A building according to any of the claims, characterized in that the upper air flow passage (87) is of increasing cross-section from the inside to the outside (Fig. 10). (Els. 25, 1986) 19. A building according to any one of claims 1 to 5, characterized in that the lower guard (19) and / or the upper guard (81a, 81b) is installed in a horizontal or substantially horizontal position (Fig. 10). (El. 25 Nov 1986) 10 20. Figures 1-19. A building according to any one of claims 1 to 3, characterized in that the roof (2) has at least one opening and closing cover (12) which is connected to the roof flange profile (22) by interposing a tongue and glazing roof closing device (14) (Figures 1 and 11). . (Els. 1986- 25) 15 Building according to Claim 20, characterized in that the opening delay-roof-re-closing device (14) is movable in a longitudinal direction (x) by a cylinder (59) connected to the roof flange profile (22) by an articulated connection (61). also having a pivot (62) hinged to the lid (12) by means of a hinged connection (62), the inner end of which has a piston (66) comprising a through hole (s) (66b) and a flexible disc (67); a section (60) of the rod (60) between the piston (66) and the outer end of the cylinder (59) being partially or wholly surrounded by a spiral spring (65), and an elastic stop member (69) is provided inside the cylinder (59). (Els. X-22, 1986) 22. A building according to any one of claims 1 to 4, characterized in that the roof flange profile (22) has a roof (12) attached thereto, or 30 with covers - with removable connections, removable and removable in one member attached to the frame structure (1). (Els. 25, 1986) A building according to claim 22, characterized in that it has a lifting eye (16) in each of its four upper corners, which also provides a releasable connection between the roof (2) and the frame structure (1), and each lifting eye (16) an outer threaded ring (71) fixed to the roof flange profile (22); it has a lifting spindle (72) with a threaded bore (72a) fixed at its lower end concentric with the lateral distance (p) and fixed to the frame structure (1), and a closure cap (73) having a threaded fastening piece (74) which can be folded into this threaded bore (72a). (Figure 13). (Els. June 22, 1986) 24. The building of claim 23, wherein the exterior has a threaded ring 45 (71) has a lifting sleeve (75) which can be folded out from the outside and threaded inside (Fig. 14). (Els. 22.10.1986) A building according to claim 23 or 24, characterized in that it has an e50 (77) having a lifting ring (78) having a threaded shaft __ (80) which can be driven into a threaded bore (72a) of the lifting spindle (72). (Els. 22.10.1986)