BE1028308B1 - Support structure for a timber frame construction and method for its manufacture - Google Patents

Abstract

The present invention relates to a support structure for a timber-frame construction, the support structure comprising at least a stud and a beam, which stud and which beam are coupled to each other in a T-shaped corner connection, with a continuous side of the T-shaped corner connection substantially comprising the stud and the discontinuous side of the T-shaped corner joint comprising substantially the beam, and wherein said post comprises a substantially U-shaped recess located between its axial ends, the substantially U-shaped recess comprising one lying face and two upright faces and wherein this recess is dimensioned to receive an axial end of the beam substantially perpendicularly, and wherein the T-shaped corner connection is fixed by means of a plate-shaped clamping element, which clamping element is between an upright surface of the recess in the stud and the beam is clamped. In a second aspect, the present invention relates to a method for manufacturing a support structure.

Description

BEARING STRUCTURE FOR A NUT SKELETON CONSTRUCTION AND PROCEDURE BEFORE MANUFACTURING THEM

TECHNICAL DOMAIN The invention relates to a support structure for a timber frame construction. More specifically, the invention is located in the technical area of corner joints In timber frame construction,

BACKGROUND ART Timber-frame construction is often applied with a view to obtaining energy-efficient homes, such as, for example, passive houses. Timber frame construction methods known from the current state of the art often focus on the strength of the construction on the one hand, eg the platform method, or thermal insulation on the other hand, eg the balloon method. In order to realize both a strong construction and a thermally favorable construction, concepts from different methods are thus generally combined, whereby complex reinforcing or fastening elements are often necessary, however. Such a combination is described, inter alia, in BE 2010/1950, in which a support structure is included which forms a combination between the balloon method and the platform method. However, the supporting structure does not manage to combine all the advantages of both methods. Moreover, the formation of corner connections between uprights and beams appears to be complex and labour-intensive. Furthermore, reinforcement or fastening elements for the formation of corner connections are described in, inter alia, JP 2006/241938 , in which a metal connector is used to connect different beams and struts together in a durable manner. However, applying such connectors to all or most of the corner joints between beams and struts is complex and labor intensive, and does not give rise to the combined strength of the platform method and the good thermal insulation of the balloon method.

© BE2020/5343 There is therefore a need for a support structure that combines the advantages of a strong and rigid corner connection with good thermal insulation. In particular, there is a need for a simplified support structure that is sufficiently strong and thermally insulating, and moreover simple, can be achieved quickly and efficiently. The present invention aims at finding at least a solution to some of the above-mentioned problems or drawbacks. The aim of the invention is to provide a method which obviates these drawbacks.

SUMMARY OF THE INVENTION To this end, in a first aspect, the invention provides a support structure for a timber frame construction according to claim 1.

Preferred forms of the support structure are shown in subclaims 2 to 13. A second aspect of the present invention relates to a method for manufacturing a support structure according to claim 14. Preferred form of the method is shown in claim 15.

DESCRIPTION OF THE FIGURES Figure 1a shows the perspective view of a preferred form of support structure comprising one twill with a coupled, substantially T-shaped corner connection between a beam and a stile according to the present invention. Figure 1b shows the perspective view of a preferred form of support structure comprising one twill with a disconnected, substantially T-shaped corner connection between a beam and a mullion according to the present invention. Figure 1e Shows the perspective view of a preferred form of support structure comprising two rafters with a coupled, substantially T-shaped corner connection between a beam and a mullion according to the present invention.

Figure 1d shows the perspective view of a preferred form of support structure comprising two rafters and vapor and air sealing plates with a coupled, substantially T-shaped corner connection between a beam and a mullion. according to the present invention. Figure 2 shows the perspective view of vapor and air sealing plates for a corner connection at the height of a post and a beam of the supporting structure according to the present invention.

Figure Za shows the perspective view of a preferred form of a supporting structure with a coupled corner connection between a roof beam and a mullion according to the present invention.

Figure 3b Shows the perspective view of a preferred form of support structure with a disconnected corner connection between a roof beam and a stile! according to the present invention.

Figure 3e shows the perspective view of a preferred form of support structure comprising vapor and air sealing plates with a coupled corner connection between a roof beam and a post according to the present invention. Figure 4 shows the perspective view of vapor and air-tight seals for a corner connection at the height of a mullion and a roof beam of the supporting structure according to the present invention,

DETAILED DESCRIPTION The present invention relates to a support structure for a timber frame construction.

Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meaning as generally understood by those skilled in the technical field of the invention. For a better assessment of the description of the invention , the following terms are explicitly explained.

* BE2020/5343 “A”, “the” and “the” refer to both the singular and the plural in this document unless the context clearly implies otherwise. For example, “a segment” means one or more than one segment.

The terms “comprise”, “comprising”, “consist of”, “consisting of”, “features”, “contain”, “contain”, “contain”, “includes” are synonyms and are inclusive or open terms that indicate the presence of the following, and which do not exclude or imply the presence of other components, features, elements, members, steps known from or described in the art.

Citing numerical intervals through the endpoints includes all integers, fractions and/or real numbers between the endpoints, including these endpoints. A first aspect of the present invention relates to a support structure for a timber frame construction, the support structure comprising at least a stud and a beam, which stud and which beam each comprise two axial ends, and which stud and which beam are coupled to each other in a T-shaped corner connection. As described herein, this corner joint comprises a continuous side and a discontinuous side, wherein the continuous side of the T-shaped corner joint comprises substantially the stud and the discontinuous side of the T-shaped corner joint comprises substantially the beam. For connecting the stud and the beam in this T-shaped corner connection, said stud comprises a substantially U-shaped recess located between its axial ends. Said U-shaped recess herein comprises one horizontal surface and two upright surfaces, the recess is sized to receive an axial end of the beam substantially perpendicularly. At least one twill is coupled to and parallel to this post, which twill is located outside the plane of the T-shaped corner joint, and which twill spans the recess. According to the present invention, the T-shaped corner joint is fixed by means of a plate-shaped clamping element, which clamping element is clamped between an upright surface of the recess in the post and the beam. The term "timber frame construction" refers to the construction method in which the load-bearing parts of a structure above the ground mainly consist of a wooden construction. or roof beams for the roof, A timber frame building is usually constructed with

© BE2020/5343 using prefabricated timber frame walls, but timber frame walls can also be built from their individual parts on site, Le. on a construction site. The term "style" refers to a beam that is used upright or vertically in timber-frame construction, and which is suitable for the construction of a timber-frame wall. The term "beam" refers to a beam which is generally used horizontally in timber frame construction, and which is suitable for the construction of a floor. The "corner connection" as described herein denotes the firm and rigid connection formed between different elements of the timber frame structure. In light of the present invention, a corner connection refers to the connection between a strut and a beam.

Although the support structure as described herein is based in part on known principles of timber frame construction, it does make some important improvements. Two often used timber-frame construction methods with accompanying timber-frame constructions are the so-called balloon method and the so-called platform method. The “balloon method” means a timber-frame method in which the studs and timber-frame walls extend from the foundation to the eaves, and where the beams and floors are suspended from the aforementioned studs and timber-frame walls. In the “platform method” the studs, timber-frame walls, beams and floors per floor individually built per floor. In this case, the timber-frame construction of an upper floor is therefore placed on the timber-frame construction of an underlying floor. With a view to building energy-efficient homes, such as passive houses, the balloon method has the advantage that insulation Diedt thanks to the uninterrupted timber-frame walls. However, the load-bearing capacity is limited here, for example, floors are placed between the walls and supported by fastening to the timber-frame walls by means of bolts.

The platform method in turn offers a better bearing capacity for the floor elements, but provides a less favorable thermal insulation, largely as a result of the interrupted timber frame walls.

The present invention concerns, as it were, a hybrid form between the platform method and the balloon method, in which the uprights and timber-frame walls continue uninterrupted, but the beams and floors bear directly on the uprights and timber-frame walls without the need for complex reinforcements.

© BE2020/5343 or fasteners. In this way, the excellent load-bearing capacity of the platform method is combined with the good thermal insulation that the balloon method offers. The invention moreover provides an efficient way of fixing the corner connection between mullions and beams, in particular by germinating a tensioning element between an upright face of the recess of the mullion and the beam. The twill also ensures a good transfer of strength in the frame at the height of the substantially U-shaped recess. The support structure as described herein results in an exceptionally good load-bearing capacity and strength, combined with an excellent thermal insulation. The nature of the support structure also allows an exceptionally fast and efficient construction.

Preferably, the plate-shaped clamping element is a plate or wedge, which is simply placed between an upright surface of the recess in the stud. and the beam can be clamped. The plate-shaped clamping element can thus and preferably be knocked or knocked into the recess. The plate or wedge can possibly be made of different materials, for example wood, wood-like materials, plastics or metals. Preferably, the plate or wedge is made of wood or plastic.

In some embodiments, the support structure comprises one truss. In some other embodiments, the support structure comprises two trusses joined on either side of the strut, located outside the plane of the T-shaped corner joint. In some embodiments, the strut and the beam as described herein composite wood products with an I-shaped cross section. These wood products are constructed in such a way, comprising a core board, a first and a second flange, wherein the core board, the first and the second flange are located in the same plane, and wherein the core board is surrounded on both sides by one of these flanges in its longitudinal direction. The structure described herein thus results in a composite wood product with a [-shaped cross section, also called I-beam. In particular, I-beams have a high strength in relation to their size and weight. A major difference with solid wood is that the I-beam can bear heavy loads with less wood mass compared to a solid wooden beam, I-beams have furthermore the advantage that they bend and/or deform less quickly than a solid wooden

/ BE2020/5343 beam, 1 beam also have good dimensions, show little or no shrinkage and are exceptionally stable. Thus, the use of I-beams contributes substantially to the strength of the support structure of the present invention described herein. In particular, the supporting structure with I-beams allows a large span, whereby deformation, e.g. deflection, of the beams is minimal. The first and second flanges as described herein are made of laminated veneer or solid wood in some embodiments. In some embodiments, the first and second flanges comprise one or more finger-jointed joints. In this case, the first and second flange are grooved on the side adjacent to the core plate, for seamless connection of the first and second flange to the core plate according to a tongue-and-groove principle. In some embodiments, the first and second Tiens are glued to the core board.

The term "finger joint" in the context of the present invention refers to a wood connection of two pieces of wood along their longitudinal axis, where the wood connection is made by means of two mating milling patterns, usually in combination with the addition of glue. finger-jointed joints are specified, inter alia, in the DIN 68140. According to some embodiments, the core board is made of a wood-like panel material, selected from the group of veneer wood, laminated veneer wood, medium density fiberboard (MDF), high density fiberboard (HDE), oriented strand board (OSB), cement wood wool board, mineral bonded chipboard, gypsum fiber board, cement bonded fiber board, solid wood board, cross laminated timber (CLT), laminated veneer lumber (LVL), or combinations thereof.The core board is preferably made of oriented strand board (OSB). , more preferably from OSB 3. OSB 3 achieves the Euro standard 5 regarding quality it of wooden structures.

A “hollow-like sheet material!” consists for the most part of solid wood, wood veneer or other wood-like components that, in different compositions, are bound or not by (synthetic} resin iim.

In some other embodiments, the strut and/or beam as described herein may be composite wood products which do not specifically have an I-shaped cross section. Such wood products may have been manufactured from a

© BE2020/5343 wood-like panel material selected from the group consisting of veneer wood, laminated veneer wood, medium density fiberboard (MDF), high density fiberboard (HDE), oriented strand board (OSB), wood wool cement board, mineral bonded chipboard, gypsum fiber board, cement bonded fiber board, solid wood plate, cross laminated timber (CLT), laminated veneer lumber (LVL), or combinations thereof. Preferably, such composite wood products are made from laminated veneer lumber (LVL). According to a further or different embodiment, the core plate, the first and the second flange of the upright and the girder, respectively, are all located in the same plane. The support structure as described herein has small volumetric dimensions and is extremely light, but exhibits extremely good strength in the whole of a timber frame construction. The rigid support structure makes it possible to span large surfaces, whereby deformation, eg deflection or torsion, is minimal.

According to a further or different embodiment, the substantially U-shaped recess extends transversely across the longitudinal direction of the first flange and transversely across the longitudinal direction of the core plate, this recess extending as far as the second flange. The configuration as described herein improves further. the rigidity of the corner connection, thus providing a supporting structure with a high load-bearing capacity. The T-shaped corner connection of the stile and the beam is, according to some embodiments, fixed by means of at least 4 screw connections. Notwithstanding the initial fixation of the corner connection is effected by means of a clamping element between an upright side of the substantially U-shaped recess of the stud! and the beam, a more permanent fixation can be provided by applying the screw connections described herein. Preferably, the T-shaped corner connection of the upright and the girder according to some Embodiments is fixed by means of at least 5, more preferably by at least 6, by at least 7, most preferably by at least 8 screw connections. According to a further or different embodiment, the screw connections extend from at least one of the flanges of the stile! to at least one of the beam flanges. Screw connections at these locations give rise to a particularly strong corner connection, with a minimum number of

° BE2020/5343 screw connections. Thus, obtaining a solid corner connection is simple, efficient and little labour-intensive.

In some embodiments, the beam and the stud are fixed by gluing. Preferably, at least one of the flanges of the stud is glued to at least one of the flanges of the beam.

According to a further or different embodiment, the stile! at one of the axial ends an L-shaped recess suitable for receiving a roof beam. The supporting structure of the skeleton building construction is thus completely suspended on continuous beams over the different levels of which the skeleton building construction occupies and thus contributes to the thermally insulating properties of the construction as a whole. However, the L-shaped recess provided as described herein allows the attachment of a roof beam to the Loe post without the need for complex stiffening or fixing elements. In this way, the excellent load-bearing capacity of the platform method is combined over all floors, including the roof, but the good thermal insulation that the balloon method offers.

Preferably, the L-shaped recess extends transversely along the longitudinal direction of the first flange and transversely across the longitudinal direction of the core plate, this recess extending as far as the second flange of the strut. The configuration as described herein further improves the rigidity of the corner connection, also at the height of the roof, and thus provides a supporting structure with a large bearing capacity and span.

According to some embodiments, the support structure is provided with an integrated gable roof curb. In traditional timber-frame construction, however, the roof curb must be provided on site. The present invention thus also provides for a further increase in efficiency with regard to the roof curb.

According to some embodiments, the roof beam is a composite wood product having an I-shaped cross section, this wood product comprising a core board, a first and a second flange, the core board, the first and the second flange being in the same plane, and the core board is surrounded on both sides by one of these flanges in its longitudinal direction.

Preferably, the first and second flanges of the roof beam are oriented relative to each other at an angle comprised between 0.1 and 30.0°. As such, the supporting structure allows to form a pitched roof with only a single type of roof beam, where the construction of a pitched roof commonly comprises a plurality of elements, and is particularly complex. However, the roof beam as described herein can be custom and prefabricated, Le. as a prefab element on a production site. As a result, on site, the assembly of the roof is limited to a number of less complex steps, resulting in a fast, efficient and qualitative construction of the roof construction. All advantages which the supporting structure confers on the construction of a floor, or on the construction of the skeleton construction, is therefore also conferred in the present embodiment on the (sloping) roof construction.

More preferably, the first and second flanges of the roof beam are oriented relative to each other at an angle comprised between 0.1 and 25.0%, even more preferably between 0.1 and 20.0%, between 0, 1 and 15.09, most preferably between 0.1 and 10.09. In some embodiments, the downwardly oriented flange of the roof beam is oriented substantially parallel to the beam of the support structure, ie. substantially perpendicular to the stile. The slope of the roof is thus only formed by the orientation of the first and second flange of the roof beam Len relative to each other, and not by a deviating angle of the roof beam relative to the stud. stability and carrying capacity.

According to a further or different embodiment, the girder comprises a substantially U-shaped recess located between its axial ends, said recess being dimensioned to receive a secondary support beam substantially transversely. The secondary support beam acts as a span transverse to the girders and further improves the general rigidity and load-bearing capacity of the supporting structure.

Preferably, the secondary support beam is made of steel or stainless steel.

According to a further or different embodiment, the support structure comprises one or more vapor and/or air sealing plates, which vapor and/or

“0 BE2020/5343 air sealing plates are positioned substantially perpendicular to the longitudinal direction of the beam or roof beam, and adjacent to the first flange of the stud. The vapor and/or airtightness sheets as described herein fit optimally to the T-shaped corner joint according to the present invention, and provide excellent vapor and/or airtightness. The vapor and/or air sealing plates preferably fall over one or more recesses suitable for receiving the beam or roof beam transversely. A good vapor and/or airtightness of the timber frame construction guarantees optimum stability and bearing capacity, and extends the life of the timber frame construction. A second aspect of the present invention relates to a method for manufacturing a supporting structure for a timber frame construction, comprising the steps: a. mounting a stud upright and substantially perpendicular to a suitable base, the stud comprising two axial ends, wherein the stud is mounted on the substrate at the level of the first axial end, which stud has a substantially U-shaped recess comprises located between its axial ends, the generally U-shaped recess comprising one lying face and two upstanding faces; b. coupling a beam to the strut, the beam comprising two axial ends, the recess of the strut being dimensioned to receive an axial end of this beam substantially perpendicularly, whereby a T-shaped corner connection is formed, comprising this corner connection a continuous side and a discontinuous side, wherein the continuous side of the T-shaped corner joint comprises substantially the stud and the discontinuous side of the T-shaped corner joint comprises substantially the beam, and wherein on and parallel to this stud at least one twill is coupled, which twill is located outside the plane of the T-shaped corner joint, and which twill spans the recess; and c. fixing the T-shaped corner connection; and wherein the T-shaped corner connection is fixed by means of a plate-shaped clamping element, which clamping element is clamped between an upright surface of the recess in the post and the beam.

Preferably, the method as described herein relates to a support structure as described in one of the foregoing embodiments. Thus, all the advantages described in the context of the support structure itself also apply to the method for its manufacture. In particular, the method described herein has the additional advantage that the elements required herein can all be prefabricated on a production site, ie. separate from the site. Moreover, its assembly on the construction site can be carried out very efficiently, and a load-bearing construction is obtained particularly quickly. greater bearing capacity, a quick, simple and efficient construction, and the possibility to create spans with a large span. In what follows, the invention is described on the basis of non-limiting examples or figures illustrating the invention, and which are not intended or should be interpreted to limit the scope of the invention.

DETAILED FIGURE DESCRIPTION In Figs. 1a-1d shows a support structure for a timber frame construction according to the present invention, which support structure comprises a rigid 1 and a beam 2, which are coupled according to a T-shaped corner connection 5. It is clear that the T-shaped corner connection 5 essentially falls apart into a continuous side, as well as a continuous side, and a discontinuous side, or thus a side bounded on one side. The continuous side of the T-shaped corner connection 5 herein consists essentially of the stiffener. 1, while the discontinuous side substantially comprises the beam 2. In order to be able to form the rigid and strong T-shaped corner connection 5, the post 1 comprises for this purpose a substantially U-shaped recess 6 which is located between the two axial ends 3,3' of the post 1. This is substantially U-shaped recess. recess 6 is thus defined by a horizontal plane 7, which plane is thus parallel to the longitudinal direction of the stile 1, and two upright faces 8,8', which are thus perpendicular to the longitudinal direction of the stile! 1. The U-shaped recess 6 is dimensioned such that it is substantially perpendicular to the beam 2, and in particular an axial end 4 of the beam 2, Le. perpendicular to the longitudinal direction of the stile 1, can record. The support structure also comprises at least one twill

8, which twill 9 is coupled to and parallel to the strut 1, and is located outside the plane of the T-shaped corner joint 5, and which twill spans the U-shaped recess &, Fixation of the T-shaped corner joint 5 is obtained by means of the presence of a plate-shaped clamping element 10, which is clamped between an upright surface 8' of the recess & in the post 1 and the beam 2 . The clamping element 10 as shown in Figs. 1a-1d concerns a plate made of wood or a wood-like material, possibly plastic or metal. It further becomes clear from the figures that the post 1 and the beam 2 can be composite wood products with an I-shaped cross section, for this purpose each comprising a core plate 11, surrounded by two flanges 12,12'. The U-shaped recess 6 here extends transversely over the longitudinal direction of the first flange 12 and transversely over the longitudinal direction of the core plate 11, and extends just as far as the second flange 12'. Permanent fixation of the supporting structure, in particular of the T-shaped corner connection 5 of the stile 1 and the beam 2, is obtained by means of gluing and/or screw connections, which extend from at least one of the flanges 12,12' of the stile 1 to at least one of the flanges 12,12' of the beam 2. The forming and gluing of the T-shaped corner connection 5 is herein possibly carried out at the level of a tongue and groove connection, wherein the beam 2 has a tongue at the height of its axial end. 4 in a groove at the level of the second flange 12° from the strut! 1 is glued.

In particular in FIG. 10 shows a similar supporting structure, which supporting structure comprises two rafters 9. These rafters 9 are coupled on either side of the style 1, located outside the plane of the T-shaped corner connection 5. In FIG. td the supporting structure is shown, which is provided with two vapor and/or air sealing plates 15. These vapor and/or air sealing plates 15 are provided with recesses 18 suitable for receiving transversely of the beam 2.

fig. 2 shows vapor and/or air sealing plates 15 as described herein, in which the recesses 16 suitable for receiving the girder 2 transversely are clearly visible.

fig. 3a-3c show the perspective view of a roof beam 14 and a post 1 of a supporting structure according to the present invention. The roof beam 14 is a composite wood product with an I-shaped cross section, comprising a core plate 11, a first 12 and a second flange 12'. The post 1 of the supporting structure comprises an L-shaped, thus open, recess 13 in which a roof beam 14 can be received, the open recess 13 extending transversely over the longitudinal direction of the first Tens 12 and transversely over the longitudinal direction of the core plate 11, reaching as far as the second flange 12° of the post 1. The forming and gluing of the corner connection at the level of the L-shaped recess 13 is possibly carried out at the height of a tongue-and-groove connection, whereby the roof beam 14 has a tongue at the The height of its axial end is glued in a groove at the level of the second flange 12° of the post 1. 30 shows the supporting structure, which is provided with two vapor and/or air sealing plates 15. These vapor and/or air sealing plates 15 are provided with recesses 18 suitable for receiving the roof beam 14 transversely. FIG. 4 shows vapor and/or air sealing plates 15 as described herein, in which the recesses 16 suitable for receiving the roof beam 14 transversely are clearly visible.

List of indicated elements 1 style! 2 lgger 3.3" axial ends of the strut 44 axial ends of the girder 5 T-shaped corner joint 6 substantially U-shaped recess of the stile! U-shaped recess 9 twill 10 plate-shaped clamping element ii core plate 12,12' first and second flange 13 L-shaped recess 14 roof beam 15 vapor and/or air sealing plate 16 recesses in the vapor and/or air sealing plate 17 roof curb

Claims (15)

CONCLUSIONS 1. A supporting structure for a timber-frame construction, the supporting structure comprising at least one stile! (1} and a beam {2}, which stud and which beam each comprise two axial ends (3.3 and 4.4), and which stud and which beam are joined together in a T-shaped corner connection (5), this corner joint comprising a continuous side and a discontinuous side, wherein the continuous side of the T-shaped corner joint mainly comprises the stud and the discontinuous side of the T-shaped corner joint mainly comprises the beam, and wherein said stud comprises a substantially U-shaped recess (6) comprises located between its axial ends, the substantially U-shaped recess comprising one lying face {7} and two upright faces (8.5), and this recess being dimensioned to receive substantially perpendicularly from an axial end of the beam, and wherein the support structure comprises at least one twill (9) which twill is coupled to and parallel to the strut, and is located outside the plane of the T-shaped corner joint, and which twill comprises the recess about truss, characterized in that the T-shaped corner connection is fixed by means of a plate-shaped clamping element (10), which clamping element is clamped between an upright face of the recess in the post and the beam. The support structure according to claim 1, characterized in that the post (1) and the beam (2} are composite wood products with an I-shaped cross section, these wood products comprising a core board (11), a first (12) and a second Hens {12}, wherein the core plate, the first and the second Tiens are located in the same plane, and wherein the core plate is surrounded on both sides in its longitudinal direction by one of these flanges, The support structure according to claim 2, characterized in that the core plate {11}, the first (12) and the second flange (127 of the strut (1) and the beam (2), respectively) are all located in the same plane. . The support structure according to claim 2 or 3, characterized in that the substantially U-shaped recess (6) extends transversely over the longitudinal direction of the first flange (12) and transversely over the longitudinal direction of the core plate (11}, and wherein this recess extends to the second flange (12%). The support structure according to any one of the preceding claims 2-4, characterized in that the twill (9) is coupled to and parallel to the first flange (123. The support structure according to any one of the preceding claims 1-5, characterized in that the T-shaped corner connection (5) of the stile! (1) and the beam (2) is fixed by means of at least four screw connections. The support structure according to claim 6, characterized in that the screw connections extend from at least one of the flanges (12,12" of the strut (1) to at least one of the flanges (12,12) of the beam (1)). 2). The support structure according to any one of the preceding claims 1-7, characterized in that the post (1) comprises at one of the axial ends (3,3) a substantially L-shaped recess (13) suitable for receiving a roof beam (14). 9, The support structure according to claim 8, characterized in that the L-shaped recess (13) extends transversely over the longitudinal direction of the first flange {12} and transversely over the longitudinal direction of the core plate {11}, and wherein this recess extends to the second flange (127). The support structure according to claim 8 or 9, characterized in that the roof beam {14} is a composite wood product with an I-shaped cross section, this wood product comprising a core board (11), a first (12) and a second flange ( 12), wherein the core plate, the first and the second flange are located in the same plane, and wherein the core plate is surrounded on both sides in its longitudinal direction by one of these flanges. il. The support structure according to claim 10, characterized in that the first (12) and the second flange (12) of the roof beam (14) are oriented relative to each other according to an angle (a) comprised between 0.1 and 30.0 °. The support structure according to any one of the preceding claims 1-11, characterized in that the beam (2) comprises a substantially U-shaped recess located between its axial ends (4, 4), this recess being dimensioned for substantially transversely receiving a secondary support beam, 40 The support structure according to any one of the preceding claims 1-12, characterized in that the support structure comprises one or more vapor and/or air sealing plates (15), which vapor and/or air sealing plates are positioned substantially perpendicular to the longitudinal direction of the the girder (2) or roof girder (14) and adjacent to the first flange of the girder! {1}. A method for manufacturing a supporting structure for a timber frame construction, comprising the steps of: a. mounting a stud upright and substantially perpendicular to a suitable base, the stud comprising two axial ends, wherein the stud is mounted on the substrate at the level of the first axial end, which post comprises a substantially U-shaped recess located between its axial ends, the substantially U-shaped recess comprising one horizontal surface and two upright surfaces; b. coupling a beam to the stud, the beam comprising two axial ends, the recess of the stud! is dimensioned to receive an axial end of this beam substantially perpendicularly, whereby a T-shaped corner joint is formed, this corner joint comprising a continuous side and a discontinuous side, the continuous side of the T-shaped corner joint being substantially the stud and the discontinuous side of the T-shaped corner joint substantially comprises the beam, and wherein on and parallel to the beam at least one twill is coupled, which twill is located outside the plane of the T-shaped corner joint, and which twill spans the recess; and c. fixing the T-shaped corner connection; characterized in that the T-shaped corner connection is fixed by means of a plate-shaped clamping element, which clamping element is clamped between an upright surface of the recess in the post and the beam. The method of claim 1e, wherein the support structure is a support structure according to any one of claims 1-13.