SE426084B - Universal frame building skeleton - Google Patents

Abstract

This invention consists of a building of light construction and a support skeleton for it which can be used both with horizontal and with somewhat sloping roofs T, and which consists of a support with a simple C- or U-shaped cross- section or multiples of this support. Both supports 1-4 and their load bearing elements 5-7 are formed with rows of holes 8, where the work at the building site is limited to screw connections. The building's netlike beam framework consists of primary beams F and auxiliary beams M arranged along an orthogonal frame, the basic elements of which consist of homogenous C- or U-shaped beams 1 or beams 2 consisting of two single beams 1 placed side by side or of simple Vierendeel beams 3 formed of a pair of simple beams 1 arranged over each other or, if applicable, by double Vierendeel beams 4 formed by a pair of simple Vierendeel beams 3. <IMAGE>

Description

7809926-4 metal is, partly that they must be assembled from a few elements, which are as similar as possible and partly how the building elements are to be connected to each other. The typability of the skeletal system and the industrialized nature of the construction method also require that the production of the connections take place uniformly.

Previously known metal building skeletons have not made it possible to build with few profiles or any uniform solution for the uniform connection points. In today's known construction methods, several different types of beams are used worldwide as elements in skeletal structures. In the places where the individual beam types meet with each other or with other beam types, new junction solutions must of course be developed from case to case. Due to very varied connection points, even the strongest desire for uniformity could not be realized in skeletal structures. In the case of hitherto partially introduced uniformity among building constructions of various kinds, in fact only one or two were satisfactorily solved, and in this respect constructions which here are called goal-oriented were achieved. This means that in the case of buildings that deviate from original conceptions, not even the skeletal structure was able to fulfill all the requirements. The object of the present invention is to provide a uniform building skeleton, which in single-storey buildings constitutes the entire building support, but which in multi-storey buildings forms support for the roof, and which is buildable in mounting methods with light construction, especially in municipal buildings.

Within the framework of this object, the invention has another task in realizing a universal construction system, which enables simple, easy-to-manufacture and mountable assembly of so-called "element housings" of directly interchangeable elements with equal construction and uniform connection solutions. This task also includes that both the building elements and the connections must be so derived from a single modular dimension that the entire construction thereby becomes dimensionally coordinable, but the assembly on the construction site becomes feasible with a minimum of physical work.

The basic idea of the invention was the realization that the versatile requirements, which have mainly emerged from the function of the buildings, can be met with a single constructive solution if - and exclusively if - the construction is built on such a beam type, which on the way to a continuous or periodically multiplied basic unit in terms of 'statistics and stability' is to the same extent grown the various requirements that can be placed on support and should ability.

This insight also includes the fact that the increase in load-bearing capacity, which is carried out by multiplication according to the addition principle, can most easily and advantageously be realized with the help of cold-bent steel profiles with a C-shaped cross-section (rarely U-shaped cross-section). The basic profile used is together with an identical profile placed next to the former easily trainable as a composite profile, together with a similar profile placed below or above the basic profile trainable as a simple Vierendeel beam, or where applicable by doubling the below assembled beams with composite profile trainable as a double Vierendeel beam. The same basic profile also enables similarity between the connections.

A universal building / skeleton of the type specified in the preamble of the appended main claims is characterized according to the present invention by the special features specified in the characterizing part of the claim.

The universal building skeleton according to the invention has several advantages. Most of these are due to the choice of beam type of the invention or to the fact that by placing two basic profiles wide »next to or above each other, where applicable even by assembling four profiles, it is possible to observe in practice required aids and load facts the entire building skeleton is functionally assembled for the most varied functional purposes through a single basic element.

The building skeleton according to the invention is just as useful for horizontal roofs as for slightly sloping roofs. The invention also provides a construction suitable for roofs with lanterns. In such cases, the roof side in every other column space can be suspended on the Vierendeelnuvudbalkena lower base beam.

It is also favorable that all parts of the building skeleton, even those that are trained as Four-part beams, can be assembled on the construction site from the basic element with a basic profile. Of course, it is also possible to assemble 7809926-4 such frames, which in their entirety can be lifted in the intended place, by pillars and associated main beams. There is also the possibility of using technology for highly efficient mounting (eg according to the "lift-slab" method).

Among the favorable properties of the universal building skeleton according to the invention, simple transports should also be mentioned. These are expressed in the fact that the main beams, which are intended for the largest span and are designed as double Four-part beams, can be transported to the construction site if required - even separated to basic profiles. The assembly is greatly facilitated by training both the beams and the connecting elements in advance with rows of holes, whereby the work on the construction site only consists of the assembly of the finished elements, as well as the insertion and tightening of connecting screws.

With reference to the accompanying drawing, various embodiments of the universal building skeleton according to the invention are described below as examples; ningen. In the drawing, Fig. 1 is a horizontal view of a suitable embodiment of the building skeleton according to the invention, in this case with main beams with a smaller span, Fig. 2 another embodiment with main beams with a larger span, fig. Fig. 3 is a vertical section along line III-III in Fig. 1, Fig. 4 is a vertical section along line IV-IV in Fig. 2, Fig. 5 is a vertical section along line VV in Fig. 2, Fig. 6 is a cross-section through The C-profile, which forms the foundation beam in the building skeleton according to the invention, and Fig. 7 an axonometric view of the C-profile according to Fig. 6 with drawn holes.

In the embodiment illustrated in Fig. 1, the built-up beam truss is formed by horizontal main beams F and horizontal auxiliary beams M. The main beams F for small span each consist of beams 2 composed of two beams with a C-profile. Each composite beam 2 is thus assembled by two homogeneous beams 1 with a C-profile, the beams 1 having their equal body parts facing each other.

The auxiliary beams M also consist of two equally homogeneous beams 1 with a C-profile. However, one beam 1 is arranged over the other and they thereby together form a simple quarter beam 3. Doubling of the homogeneous beam 1 serving as a basic profile is required here due to the large span of the auxiliary beams M. Auxiliary beams M for small spans are also designable as single homogeneous beams 1 with a C-profile. 7809926-4 The life parts of the simple quarter beams 3, which form the auxiliary beams M, are connected in scattered places by means of tie beams 6, which likewise preferably have a C-profile and form the pillars of the simple quarter beams 3. The main beams F are so connected to the pillars O that their individual beams seen in the horizontal plane together enclose the pillars O.

The cross-section of the columns 0 can of course be made as a profile, accommodating between the half-cross sections of the main beams F, each of which is formed as a composite beam 2, and on the accommodated portion the connection between the column O and the main beam F is feasible. Preferably, an I-profile with a wide flange is usable, but even more preferably a closed tube-like profile is used, which is for instance composed of C- or U-profiles by welding, the open sides of the individual beams facing each other.

In the embodiment of the building skeleton according to the invention illustrated in Fig. 2, the auxiliary beams M are formed for a small span, and are therefore formed by the basic profile of the skeletal structure, ie by the homogeneous beams 1 with C-profile. For this reason, no tie beams to the auxiliary beams M are drawn in the figure. In this embodiment, the span of the main beams F is assumed to be so large that the composite beams 2 are no longer sufficient to take over the load, but double quarter beams 4 must be used by doubling the former. The separate life parts of the main beams F, which are formed as double quarter beams, are assembled with tie beams 7 so that they cooperate. These connecting beams 7 are also formed of material with a C-profile, preferably by doubling, and then, for example, with the open sides facing each other, so that a closed tube is formed.

From Fig. 3 it can be seen that the main beam F is formed as a composite beam 2, while the auxiliary beam M is formed as a simple Quarter beam 3.

The tie beams 6, which enable interaction between the profiles of the auxiliary beam, have an increasing height from left to right in the figure. Due to the dimensionally coordinated change in height, the roof plate T can be given the intended slope.

The building skeleton according to the invention is hereby used not only in buildings with horizontal roofs, but also in buildings with slightly sloping roofs. Fig. 3 further shows that the outermost auxiliary beam M also serves as an edging, and extends along the roof edge.

It can also be seen that the head of the column O projects between the half-cross sections 7809926-4 O \ of the main beam F, which is designed as a composite beam.

Fig. 4 shows that the beams F here are formed as double quarter beams 4. The tie beams 7, which enable interaction between the individual basic profiles of the double quarter beam 4, have a closed cross section, formed by C-profiles facing each other, which is also shown in fig. 2. In this embodiment, the roof plate T does not tilt, as the simple auxiliary beams M formed as simple quadrilateral beams 3 therefore have equal height measurements.

The main beams F and the auxiliary beams M are fastened to each other by means of binding members D, which are likewise made with a C-profile.

From Fig. 5 it can be seen that the invention, by raising every other pillar gap, easily achieved a hall construction with lanterns.

This figure also shows that the pillars 0 project between the life parts of the opposite beams of the double quarter beams.

The heads of the columns O not only fulfill the task of enabling the main beams F to take over the load, but they also serve as organs, here referred to as the Fourteenth Pillars, which in the form of tie beams enable interaction between the profiles in the double Quadrilateral beams 4. The main beams F and the columns O joined by screw joints. The column heads are also preferably designed as C-profiles and thereby suitably so that the open side of the C-profile faces the central axis of the column 0. The binding members D also fulfill different tasks and are suitably manufactured from C-profiles. In addition to the connection between the main beams F and the auxiliary beams M, the connecting members D can also play a role in tilting the roof and further in stiffening the sub-profiles of the main beams against deflection. If the auxiliary beams M are formed as simple quarter beams 3, they can also replace their tie beams 6.

In general, both the auxiliary beams M and the main beams F are supported in several places and suitably also formed with internal connections 5, whereby the individual beam sections have been given the ability to undergo independent deformation, and to become statically determinable structures independently of each other. Also for this reason, there is a possibility that either the main beams F or the auxiliary beams M are formed with end brackets.

The building foundations have not been shown in the figures. They are arbitrary. The columns 0 are also connectable to the foundation according to their own choice, articulated in both main directions, or articulated at both ends, or finally articulated at one end and clamped at the other.

The base beam with C-profile, which gives the homogeneous beam 1, is shown on an enlarged scale in Fig. 6. The C-profile consists of three characteristic sections: the waist part g, the flanges t which connect to the waist part, and the edge parts p which are manufactured as edgings on the flanges. By placing two base beams 1 with C-profile next to each other, the composite beam 2 with separate profile parts is obtained, and by placing a homogeneous beam 1 above or below another such beam, a simple quarter beam 3 with life parts in the same plane, while in the case of two composite beams 2, one placed below or above the other, a double Vierendeelbeam 4 is obtained with four basic profiles separated from each other. In principle, it is desirable that the building's beam trusses are only manufactured from horizontal beams with the same C-profile, but it is of course also possible to use different C-profiles, e.g. with the intention of achieving weight loss or for hanging a ceiling, etc.

The cross-sectional dimensions of the C-profile hg, ht, hp for the body part, the flanges and the edge strips are preferably integer multiples of the micromodule etc., which are derived from the module dimension m of the building skeleton and which suitably form its integer fraction. According to experience, it is appropriate for the C-profile to contain certain proportions between the g of the body part, the t of the flanges and the cross-sectional dimensions of the edgings. The cross-section seems to be the most favorable, at which the dimensions hq: ht: hp relate to each other as 8: 3: 1. With regard to statics and stability, the cross-section is also quite favorable, at which hgzhtzh = 6: 3: 1.

It should also be noted here that the distance measurements of the building skeleton, such as column distances, beam support distances, inner wall distances at half-profiles, flange division, etc., must also be integer multiples of the basic module m and the micro-module etc. Likewise, the holes 8 of the C-profiles, which are part of the rows of holes prefabricated at the factory, must have a distance from each other and from the profile ends which are integer multiples of the micro-module etc., which are derived from the basic module m. that the individual holes of the rows of holes 8 are distributed in this way, both in the longitudinal direction x of the C ~ profile axis and in the transverse axis direction y perpendicular thereto.

According to experience, the minimum hole distance, for example in the x-direction between the 8 holes of the row of holes, must be twice as large as the minimum hole distance ey in the y-direction. The distance of the holes 8 from the intersecting lines between the plane of the body part and the plane of the flanges must at least amount to the size of a micromodule etc. In addition to the C-profiles, which form the horizontal beams, the binding beams 6 and 7, as well as the D C-profiles of the binding members, should preferably be formed with holes 8. As a result, the assembly is limited, in addition to joining, only to the insertion of the screws in the holes located opposite each other and tightening of these screws.

The homogeneous beams 1, the composite beams 2, the single Vierendeel beams 3 and the double Vierendeel beams 4 included in the skeleton of the building, as well as their complementary elements are easily and productively manufactured at the factory. The C-profiles are suitably cold-formed thin-walled profiles. When connecting the elements in the factory, various welding methods are useful, as well as loose or tightened screw connections, if applicable also adhesive connections or soft soldering. ' Only screw connections are used on the construction site. The equal character of the profiles and the uniform design of the connections in combination; with a structure according to a modular system, enables highly automated work.

The fact that the C-profiles are also formed with rows of holes according to the micro-module derived from the module m, etc., means that both beams and connecting elements only need to be cut to the intended dimensions for an arbitrary building construction to be deliverable practically "from stock". The total, but at the same time unforced dimensional coordination means that the building skeleton is insertable into every other previously known building system.

Claims (15)

7809926-4 Eatentkrav Universal building structure, in particular as load-bearing beam systems for light single-storey buildings, formed by vertical pillars (0) and horizontal beams (F, M) connected to the pillars and trained with or without end brackets, and where applicable together with complementary further beams, the individual elements of the beam system preferably by means of screws of equal diameter being accessible at the construction site to the building skeleton, which elements, at least seen in horizontal view, are dimensionally coordinated and joined to a truss, which is preferably built on a single base module (E). the length dimensions of the beam elements are adapted to the basic dimensions of the module truss and the holes (8) of the screw connections are integral multiples of a micromodule (mm) derived from the base module (E), and the sub-beam elements of the beam system directly or via a connecting element rely on beam elements of higher order and the building itself is formed with a roof pl atta, characterized in that the horizontally built-in beams (F, M), which support the horizontal or slightly sloping roof slab of the building, are arranged in the same or parallel horizontal planes along a net-like, seen in the horizontal plane rectangular beam formed by main beams (F) and auxiliary beams (M), that the sub-elements of the beam structure consist of four types of beam types related to each other, such as homogeneous beams with C- or U-shaped base profile (1), beams (2) composed of two base profiles ( 1) placed next to each other, simple Quadrilateral beams (3) composed of two basic profiles (1) with the body parts in the same plane, or double Quadrilateral beams (H) formed by two simple Quadrilateral beams (3), the main beams (F) and the pillars (0) are rigidly or articulated connected to each other and are always formed as composite beams (2) or as double Fourth sub-beams (U), between which adjacent sub-profiles (1) the pillars (0) project, and wherein the auxiliary beams a (M) are preferably supported in several places, while the main beams (F) are supported in two or more places, and in order to achieve a statically determinable load drop, the beams (M, F).,, _, -_. 7809926-4 are preferably interruptions with internal connecting joints (5), and furthermore both the main beams (F) and the auxiliary beams (M) are, where applicable, formed with brackets and the main beams (F) and the auxiliary beams (M). therefore lie in different planes, and finally the homogeneous beams (1) made of C-profiles and U-profiles, the composite beams (2), the single Quadrilateral beams (5) and the double Quadrilateral beams (H), as well as the tie beams (6) which enable co-operation between the parts of the quarter beams (3, Ä), to enable total prefabrication and direct replaceability and, where applicable, sloping roof plate and to enable the installation of mechanical connecting elements, e.g. screws, are formed with a hollow row (8), the division of which is r follows the selected basic module (E). ' Building skeleton according to claim 1, characterized in that the pillars (0) are clamped or articulated connected in both horizontal main directions in a building foundation, or clamped in one main direction and articulated - connected in the other, while themselves the column (0) consists of, for example, an I-profile with at least one wide flange, or preferably of a closed tube, which is formed, for example, of C- or U-profiles, the open sides of which face each other. Building skeleton according to Claim 1 or 2, characterized in that the auxiliary beams (M) in the case of small spans consist of the homogeneous beams (1) with Ce or U-profile, but in the case of large spans of the simple Quarter beams (3). M. Building skeleton according to one of Claims 1 to 3, characterized in that the main beams (F) in the case of small spans consist of the composite beams (2) with C- or U-cross-sections, but in the case of large spans of the double quarter beams ( H), whose tie beams (6) have closed cross-sections and are formed by C- or U-profiles, which have the open sides facing each other. Building skeleton according to Claim 3 or H, characterized in that the auxiliary beams (M) and the main beams (F) are connected to one another by means of binding members (D) with a C- or U-profile. Building skeleton according to one or more of Claims 7899926-4 11 F 1 - 5, characterized in that in the case of main beams (F) formed as double Quadrilateral beams (U), the heads of the columns (O) are designed as tie beams with C- or U- profile and with hollow rows (8) for mounting. Building skeleton according to one or more of Claims 1 to 6, characterized in that the cross-sectional dimensions (hg, ht, hg) of the body part (g), the flanges (t) and the edge strips (p) on the C-profile, which form the basic beam of the homogeneous beam (1), the composite beam (2), the single quarter beam (5) and the double quarter beam (U), are integer multiples of the micromodule (EE). Building skeleton according to Claim 7, characterized in that the cross-sectional dimensions (hg, ht, hp) of the web part (g), flanges (t) and edgings (p) of the C-profile have predetermined proportions relative to one another, preferably in the ratio hgzhtzhp = 8:}: 1 or hgzhtzhp = 6: 3: 1. Building skeleton according to Claim 7 or 8, characterized in that the distance (ex, ey) between the holes in the rows of holes (8) made for the connecting elements in the direction (x) of the longitudinal axis of the C-profile, as well as in the direction perpendicular thereto (y) are integer multiples of the micromodule (Em). Building skeleton according to Claim 9, characterized in that the minimum hole distance (ey) in the transverse direction of the C-profile amounts to half the hole distance (ex) in the longitudinal direction (X) of the profile. Building skeleton according to one or more of Claims 7 to 10, characterized in that the C-profiles are cut along the bisector between the hole distances in the X-direction and that the section lengths of the C-profiles thereby become integer multiples of the micromodule (mm) and thus also of the basic module (E). Building skeleton according to claim 5, characterized in that the holes (8) in the binding members (D) both in the web part (g) and in the flanges (t) are formed with a distance of a micro-module (mm) from the intersecting lines between outer plane (g) and flanges (t). Building skeleton according to one or more of Claims 1 to 6, characterized in that the C-profiles, which form simple quarter beams (3), or which form profiles in the auxiliary beams (M) with a large span, to shape and dimensions correspond to the shape and dimensions of the auxiliary beams (M) designed as homogeneous beams (1) with a small span. IN 14.. Building skeleton according to one or more of Claims 1 to 6, characterized in that the C-profiles in the composite beams (2), which in pairs form the main beams (F) formed as double quarter beams (N) with a large span, in dimensions and shape corresponds to the C-profiles in the main beams (F) designed as composite beams (2) with a small span. Building skeleton according to one or more of Claims 1 to 13, characterized in that in the case of a roof which deviates from the horizontal plane, the design of the main beams (F) and the auxiliary beams (M) corresponds to the main beams (F) and auxiliary beams (M ), which is used for horizontal roofs, but that the slope of the roof plate is achieved by installing the binding member (D) with varying height.