FR2610021A1 - Versatile frame, in particular a metal frame with cross-braced framework - Google Patents

Abstract

The invention relates to a versatile frame which will find its application in particular on building or public works sites. According to the invention, the frame has a structure with a cross-braced framework formed by an assembly of bars 2 hinged in the region where they are fixed together. The frame has means for adapting its dimensions and moments of inertia by virtue of the use of bars 2 with adjustable length. The invention relates more particularly to the industry of metal construction.

Description

 The invention relates to a universal frame. It will find its application in particular on building construction sites or public works.

 A frame is a support construction formed by an assembly of beams and support posts. The wood that was once widely used has now given way to metal frames.

 The role of a frame being to resist a set of external forces, it is constructed in such a way that the elements which compose it receive the lowest possible stresses with a direction of efforts which are favorable to them.

 It is also necessary to reduce the deformations of the frame under the action of external forces, deformations which arise due to the elasticity of the materials used.

 Metals such as steel are generally used for their mechanical property and their cost. They are perfectly resistant to traction and compression. The spans must however be limited to avoid the phenomena of buckling during compression.

 This is how the triangulated frameworks appeared. These are structures formed by an assembly of articulated bars at their ends. In the case of the formation of a beam, an upper spar and a lower spar are produced more particularly, both connected by straight or oblique crosspieces.

Any force applied to the beam in its central cantilevered part results in compression of the upper beam and traction of the lower beam. No deformation of the two beams is encountered due to the presence of the crosspieces which hold the two beams with a constant gap. The presence of the joints at each end of the bars means that none of them can undergo bending and they all work in optimum conditions. By resecting a construction symmetry, it is possible to prevent the bars from being subjected to torsional forces.

 In practice, this type of structure is produced using profiles fixed using rivets, bolts or welding and specially constructed for a given application. In fact, two parameters must guide the builder in his choice of frame. First of all, the dimensions of the support must be brought into play. of the overhang, the size of the support or others. It is necessary that the structure can very precisely rest on the support points and apply to the place where the load must be supported.

According to each case of species, it is advisable to manufacture a frame with adapted dimensions.

 Then, the resistance of the frame which is a function of its moment of inertia must be calculated to meet the constraint, this in compliance with safety standards. It is possible to adjust the moment of inertia of a structure such as a beam either by modifying its geometry or by increasing the section of the profiles used. By moving the lower and upper spar apart, the moment of inertia of the beam is increased. this with a constant profile section.

 In the case of the construction of certain temporary frameworks such as scaffolding, it is interesting to be able to modify the dimensions of the framework at will according to the configurations encountered. For this purpose, we use for the construction of metal busbars and fastening systems which allow to link the different bars. The bars can be fixed at any level of their length, which allows to adapt very precisely the dimensions of the construction to the needs. Since there is no possibility of rotation at the fixing points, the bars can work on bending and residual stresses can be created during construction. Under these conditions, the materials are not exploited at best and the structure is heavy compared to the efforts which it is likely to support.

 The main object of the present invention is to present a universal frame which can adapt to any type of configuration, in particular these dimensions can be adapted to the circumstances and its mechanical resistance can also be modulated to support variable forces.

 In addition, the assembly elements are removable, which also makes it possible to apply the universal frame of the present invention to temporary constructions.

 The structure of the frame is of the triangulated frame type, that is to say that the materials are used to the best of their mechanical property. Only tensile and compressive forces are encountered and the use of metallic materials of standard type can perfectly be envisaged.

The universal frame of the present invention may be of the "two-dimensional" type, that is to say built to withstand a set of forces belonging to a single plane, or of the "three-dimensional" type, that is to say - say likely to resist efforts directed in all directions
On the economic level, the use of standard profiled materials makes it possible to appreciably lower the manufacturing costs and thus allows a wide dissemination of the invention.

 Other objects and advantages of the present invention will appear during the description which follows which is however given only for information and which is not intended to limit it.

 The universal frame which will find its application in particular on building construction sites or public works composed of a triangular frame structure formed by an assembly of articulated bars at their removable connection, characterized by the fact that it has means of adapting its dimensions and moments of inertia.

The invention will be better understood on reading the following description accompanied by attached drawings, among which:
- Figure 1 illustrates a triangulated frame structure.

FIG. 2 represents a frame with a double moment of inertia,
FIG. 3 represents a universal frame of the "three-dimensional" type,
FIG. 4 represents a first mode of construction of a bar according to the present invention,
FIG. 5 illustrates in detail the means of discrete adjustment of the length of the bar of FIG. 4,
FIG. 6 represents in sectional section view the discrete fixing means of FIG. 5,
FIG. 7 represents the continuous means for adjusting the length of the bar of FIG. i,
FIG. 8 illustrates a second preferred embodiment of the bars of the universal frame of the present invention,
FIG. 9 represents the discrete adjustment means of the length of the bar of FIG. 8,
FIG. 10 shows in sectional section view the discrete adjustment means of the length of the bar of FIG. 9,
FIG. 11 shows diagrammatically the continuous means for adjusting the length of the bar of FIG. 8.

 The present invention relates to a universal frame which will find its application in particular on construction sites of buildings or public works.

 We have known for a long time the need to use frameworks which constitute in a construction the resistant element to which the forces refer.

 In a frame, one distinguishes the columns, or pillars which are of vertical construction and the oblique or horizontal beams. Their structure is identical only their installation distinguishes them.

 Among the different types of structures likely to be used to build a framework of frames, the triangulated type has many advantages. This structure is composed of a set of bars assembled at their ends by means of an articulated link.

 By respecting a certain symmetry of construction, the bars are only subjected to compressive or tensile forces, that is to say with regard to metallic constructions, the type of stresses which they are capable of absorbing.

 Traditionally, triangulated frames are made from profiled irons cut to measure and assembled using rivets, bolts or welding. The different bars are cut to measure to form the pillar or beam of the desired size.

 In addition, the moment of inertia of 1 set must be adapted to the effort to be supported. The choice of the section of the profiles as well as the construction geometry must be made after determining the stresses to be supported.

Given the specificity of this type of construction, only the final frames are built with this type of
structure.

Temporary structures such as those encountered in the construction of scaffolding use tubes and square tube assembly devices. The tubes can thus be linked together at a right angle and therefore must be able to withstand bending or even torsional stresses. This kind of
structure is heavy compared to the efforts which it is likely to support. Its only advantage is to be removable and to use standard elements for its construction.

 The universal frame of the present invention is classified in the category of triangulated frameworks, that is to say that it is formed by an assembly of bars articulated at their connection.

 Figure 1 shows schematically a beam 1 with triangulated frame, however this method of construction could also have been envisaged for the realization of a pillar. The bars 2 are articulated at their mutual connection 3 and therefore only undergo traction or compression forces.

 According to the main characteristic of the invention, the frame has means for adapting its dimensions and moments of inertia. Thus, whatever the distance between the support points 4 and 5 meetings, the beam 1 of the present invention can be lengthened or shortened continuously to adapt very precisely to the values encountered.

 Similarly with regard to the moment of inertia, it can be adjusted so that the structure can withstand the stresses to bear.

 By choosing for the fixing of the bars 2 of the removable assemblies 3, the universal frame of the present invention can be constructed and dismantled to form a temporary framework with a triangulated structure, that is to say which enjoys excellent stress resistance properties. .

 FIG. 2 represents a beam 1 in perspective which comprises two lateral faces 6 and 7 with a triangulated structure, while the upper 8 and lower 9 faces are only formed by an assembly of bars 2 cross-members. This type of structure withstands vertical forces well.

 Figure 3 shows in perspective a beam 1, all the faces 6, 7, 8 and 9 of which are made up of a structure of the triangulated type. This type of beam can perfectly withstand both vertical and horizontal forces.

 The means for adapting the dimensioning and moment of inertia of the frame are in the form of bar 2, the length of which is adjustable. Figure 4 illustrates a first embodiment of such a bar 2. The advantages of this type of construction are multiple because not only is it possible to refine very precisely the dimensions and moments of inertia of the final frame, but also it is possible to use only one type of bar for the total construction of the frame. Indeed, thanks to the possible extension of the bars 2, the same type of bar can be used both to form the diagonal of the triangulated structure and to form the transverse or longitudinal elements.

 According to the invention, the bars 2 have means of adjusting their discrete and continuous length.

 The structural elements (bars) can be of variable moment of inertia depending on their length and the arrangement of the forces supported by the frame.

 The body 10 of the bar is formed of a pair of elements 71 and 12 juxtaposed and provided with several fixing points 13.

 In the example chosen here, the body 10 of the bar 2 is formed of two telescopic tubular elements 11 and 12 fitted one inside the other.

 As illustrated in FIG. 5, the parts 11 and 12 are drilled regularly by bores 13, which makes it possible to adjust the length of the assembly, discreetly by the choice of the positioning of the transverse bolts 14 fixing the parts 11 and 12 assemblies as illustrated in FIG. 6. Preferably, the cross bolts 14 and bores 13 are adjusted.

 The discreet adjustment of the length of the bar 12 is obtained approximately by adjusting the length of the body 10 of the said bar 2.

 The fine adjustment of the length of the bar 2 is carried out by means of the continuous adjustment means which are formed by a screw device 15 as illustrated in FIG. 7 disposed at the end of the bar 2. This screw device 15 comprises a screw 16 secured to the extreme attachment tab 17 and a nut 18 is fixed to the end of the body 10. By rotation of the threaded rod 16, it can more or less drive it inside the body tubular 10 of the bar 2 to adjust the center distance of said bar. It should be noted that the precision of the length adjustment is equal to half the pitch of the thread of the threaded rod 16. By adopting a fine pitch, the precision is more than sufficient.

 To allow continuous adjustment of the length of the bar from a minimum value corresponding to a deep penetration of the element 11 inside the element 12 of the body 10 of the bar up to a maximum value of the length of said bar corresponding, on the contrary, to an extreme outlet of the element 11 relative to the element 12, the length of the thread of the rod 16 must at least correspond to the spacing existing between the different bores 13.

 FIG. 8 illustrates a second embodiment of the bar 2. According to this design, the body 10 of the bar 2 is formed by an assembly of two L-shaped angles 11 and 12 regularly drilled by bores 13 as illustrated in the figure 9 and which are assembled by means of bolts 14 as illustrated in FIG. 10.

 As in the previous embodiment, the length of the body 10 of the bar 2 can be adjusted by displacement of the fixing bolts 14 so that there is an approximate adjustment of the length of the bar 2 relative to the needs.

 The fine adjustment of the length is obtained by means of a screw device 15 as illustrated in FIG. 11 placed at the end of the bar 2 and which is formed by a screw 16 secured to the lug fastener 17 and which is screwed into a nut 18 fixed to the end of the body 10 of the bar 2.

 Because of this possibility of fine adjustment of the length of the bar 2, it is possible during the construction of the frame to slightly modify the length of the different bars so that for example the construction has from the outset a counter-jib .

 One could also provide each end of the bar 2 with a device for adjusting the length of the screw 15. By using reverse screw threads for each end, the rotation of the central body would make it possible to modify the geometry of the frame after assembly.

 Although all types of materials could be used for the construction of the universal frame of the present invention, mechanically welded metal constructions will be preferred with a judicious choice of steels according to the constraints to be supported.

 Other implementations of the present invention, within the reach of those skilled in the art, could also have been envisaged without departing from the scope thereof.

Claims (10)

 1. Universal frame which will find its application in particular on building construction sites or public works whose structure composed of pillars or beams is triangular frame formed of an assembly of bars (2) articulated at their connection, characterized by the fact that it presents means for adapting its dimensions and moments of inertia.  2. Universal frame according to claim 1, characterized in that the means are in the form of bars (2) whose length is adjustable.  3. Universal frame according to claim 2, characterized in that the bars (2) have means of aJustement discrete and continuous.  4. Universal frame according to claim 3, characterized in that the discrete adjustment means are formed by the body (10) of the bar (2) composed of a pair of elements (111 and (12) juxtaposed with several fixing points (13).  5. Universal frame according to claim 4, characterized in that the elements (11) and (12) of the body (10) of the bar (2) are telescopic.  6. Universal frame according to claim 3, characterized in that the continuous adjustment means are formed by a screw device (15) composed of a threaded rod (16) integral with the lug (17) and a nut (18) fixed to the end of the body (10) of the bar (2).  7. Universal frame according to claim i, characterized in that the fixing of the elements (11) and (12) of the body (10) of the bar (2] is formed by transverse bolts (14) and a set of 'bores (13> regularly spaced along the elements (11) and (12).  8. Universal frame according to claim 7, characterized in that the transverse bolts (14) and bores (13) are adjusted.  9. Universal frame according to claim 8, characterized in that the length of the thread of the threaded rod (16) of the screw device (15) is at least greater than the spacing existing between the bores (13) of the elements ( 11) and. (12) of the bar (2).  10. Universal frame according to claim 4, characterized in that the elements (11) and (12) of the body (10) of the bar (2) have an L-shaped or tubular profile.