BE1030828B1 - REUSABLE SUPPORT BEAM FOR ROOF OF CONCRETE FRAMEWORK AND A CONCRETE FRAMEWORK CONSTRUCTED WITH SUCH SUPPORT BEAMS - Google Patents

Abstract

The present invention relates to a support beam for roof support of a concrete frame building, wherein the support beam is formed by a concrete volume extending in the longitudinal direction, with a T-shaped cross-section perpendicular to the longitudinal direction, formed by a stroke and an arm, wherein the support beam at each corner formed by the stroke and the arm comprises a concrete reinforcement volume, the concrete reinforcement volumes being bounded by the stroke, the arm and an inclined wall extending from a free end of the arm to the stroke, the support beam being attached to each end and on both sides of the stroke a flat recess in the sloping wall, parallel to the arm, whereby a perforation runs parallel to the stroke of the flat recess through the arm. The invention also relates to a concrete frame structure and a method for constructing it.

Description

1 BE2022/5687

REUSABLE SUPPORT BEAM FOR ROOF OF CONCRETE FRAMEWORK AND A

CONCRETE FRAMEWORK CONSTRUCTED WITH SUCH SUPPORTING BEAMS

TECHNICAL DOMAIN

The present invention relates to a support beam, more specifically to a reusable support beam for roof support of a concrete frame building. The present invention also relates to a concrete frame building and a method for constructing a concrete frame building.

STATE OF THE TECHNOLOGY

Concrete frame buildings are known from the state of the art. A concrete frame building is a building that includes a network of concrete columns and concrete tie beams that form the structural frame of a building. This network of beams and columns is usually built on a concrete foundation and serves to support the floors, roof, walls and cladding of the building. Concrete frame buildings are often used for larger buildings, such as office buildings, apartment buildings and industrial buildings. The network of columns and beams can be cast on site or prefabricated elements can be used.

The main advantage of a concrete frame building is that the network of columns and beams form a sturdy framework, which simplifies the actual design and construction of the building.

The same sturdy skeleton, on the other hand, is also the biggest disadvantage. The use of a larger building may change over the years. This especially applies to office buildings and industrial buildings. The needs of companies evolve over time, making a building no longer suitable. The building needs to be adapted, but this is often not possible due to the sturdy skeleton that does not fit the desired new layout of the building. Because the columns and beams are attached to each other with mortar, cement, mortar and the like or are cast on site in one piece, it is also impossible to change the framework. As a result, the entire building is demolished. For the same reason, no part of the frame can be reused in the construction of the new concrete frame building. This results in a high ecological footprint.

> BE2022/5687

Another disadvantage of known buildings with a concrete frame is that the construction of the concrete frame often requires all kinds of custom-made beams.

This increases design and construction costs, but also hinders the reuse of beams. This is especially true for roof support beams.

Another disadvantage is that a traditional roof construction of a concrete frame building leads to loss of height within the concrete frame building. Traditional roof construction includes support beams and transoms attached to concrete columns at varying heights. This is a disadvantage, especially in the case of a warehouse, because the lowest point of the roof construction determines the permitted stacking height in the warehouse.

The invention aims to provide a solution to at least some of the above problems.

SUMMARY OF THE INVENTION

In a first aspect, the present invention relates to a support beam according to claim 1.

This support beam has a low weight and high strength thanks to its T-shaped cross-section and the volumes of concrete reinforcement in the corners formed by the stroke and arm of the T-shape. The flat recesses in the sloped wall at each end of the support beam and on both sides of the strike are advantageous for releasing the support beam from columns of a concrete frame of a building. The support beam is suitable for use with a flat surface defined by the arm of the

T-shape, to be placed on the columns or on column corbels and to be disconnected from the columns using connecting means through the perforations, such as bolts and nuts or threaded rods and nuts or threaded bushes and bolts. The flat recesses allow the connectors to be tightened to securely attach the support beams to the columns.

Because the support beam is provided with perforations on both sides of the stroke and because the support beam is suitable for being placed with the flat surface, defined by the arm of the T-shape, on the columns or on column corbels, the support beam suitable to absorb torsional forces in the longitudinal direction of the support beam. It is no longer necessary to attach the support beams in a non-removable manner with, for example, mortar, cement or mortar

3 BE2022/5687 to obtain a sturdy frame. This makes it possible to adapt the concrete skeleton of a building if necessary or at least to reuse the support beams when a building is demolished, enormously reducing the ecological footprint of a concrete frame building using support beams according to the current invention. The T-shape of the support beam is also advantageous because the support beam can be placed higher, through an upper surface formed by cross beams of a roof support of a concrete frame building, while retaining the same strength as traditional I-shaped support beams. Traditional I-shaped support beams cannot extend through that plane, which reduces the useful stacking height in a warehouse, for example.

Preferred embodiments of the support beam are shown in one of claims 2 to 6.

A specific preferred embodiment concerns a support beam according to claim 6.

The corbels on either side of the strike are advantageous for reducing the number of columns in a concrete frame building, while maintaining a sufficiently dense grid of support beams and transoms, creating more open space in the concrete frame building.

In a second aspect, the present invention relates to a frame building according to claim 7.

A concrete frame building according to claim 7 has the advantage that the roof support of the concrete frame is formed by support beams and concrete cross beams that are releasably attached to the columns of the concrete frame with connecting means, so that the concrete frame can be changed when the concrete frame building has to be adapted to changing needs. of the users of the concrete frame building. At least the support beams and the concrete cross beams can be reused for the construction of the roof support of a new concrete frame building when the current building is demolished. The concrete frame building therefore results in a smaller ecological footprint.

Preferred designs of the concrete skeleton building are shown in one of claims 8 to 13.

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A specific preferred embodiment concerns a concrete skeleton building according to claim 12.

This embodiment is advantageous for the construction of the roof support of a concrete frame building with standardized and identical cross beams.

This roof support should be sloped to facilitate drainage of water on the roof. Therefore, the transoms are usually shaped differently from transoms of other levels of the concrete frame building to achieve the required slope. Depending on the slope required, a different shape of support beam must be manufactured. The required slope for the roof support is obtained by placing the elastomer blocks under the transoms, the angle between the upper surface and the lower surface of which corresponds to the required slope. Identical cross beams can be used regardless of the slope, reducing costs and simplifying the design and construction of the concrete frame building.

In a third aspect, the present invention relates to a method according to claim 14.

The method is advantageous for the construction of a concrete frame building that can be adapted to the changing needs of the users of the concrete frame building or that at least allows the reuse of support beams and transoms for the construction of a new roof support of a concrete frame building when the building is demolished. The method reduces the ecological footprint of the construction of a concrete frame building.

Preferred embodiments of the method are shown in claims 14 to 16.

DESCRIPTION OF THE FIGURES

Figure 1 shows a top view of a roof support of a concrete frame building according to the state of the art.

Figure 2 shows a side view of a support beam according to an embodiment of this invention.

Figure 3A shows a section along axis A-A of the support beam of Figure 2.

Figure 3B shows a section along axis B-B of the support beam of Figure 2. 5

Figure 4 shows a detail of a section along the axis C-C of the support beam of Figure 2.

Figure 5 shows a side view of a crossbeam according to an embodiment of this invention.

Figure GA shows a section along axis A-A of the crossbeam of Figure 5.

Figure GB shows a section along axis B-B of the cross beam of Figure 5.

Figure 6C shows a section along axis C-C of the crossbeam of Figure 5.

Figure 6D shows a section along axis D-D of the crossbeam of Figure 5.

Figure 7 shows a detail of a side view of a concrete skeleton according to an embodiment of this invention.

DETAILED DESCRIPTION OF THE INVENTION

Unless otherwise defined, all terms used in the description of the invention, including technical and scientific terms, have the meanings commonly understood by those skilled in the art of the invention. As further guidance, term definitions are included to better understand the teachings of the present invention.

As used herein, the following terms have the following meanings:

“A”, “the” and “the” refer to both the singular and the plural, unless the context clearly indicates otherwise. By way of example, "a compartment" refers to one or more compartments. “Include”, “comprising”, and “includes” and “consisting of” as used herein are synonymous with “include”, “containing”, or “contains” and are inclusive or open

6 BE2022/5687 terms that indicate the presence of what follows, for example component, and do not exclude the presence of additional, not mentioned components, features, element, parts, steps, which are well known in the prior art or described therein .

Furthermore, the terms first, second, third and the like are used in the description and in the claims to distinguish between similar elements and not necessarily to describe a sequential or chronological order, unless otherwise specified. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the invention described herein may be practiced in any order other than that described or illustrated herein.

Quoting numerical ranges by endpoints includes all numbers and fractions that fall within that range, as well as the endpoints cited.

While the terms "one or more" or "at least one", such as one or more or at least one member(s) of a group of members, are self-evident, by way of further examples the term includes reference to one of the named members, or to two or more of the named members, such as for example every 23, 24, 25, 26 or 27 etc. of the named members, and even to all the named members.

When this specification refers to "one embodiment" or "an embodiment" it means that a particular feature, structure or feature described in connection with the embodiment is included in at least one embodiment of the present invention. Thus, the terms "in one embodiment" or "in an embodiment" at various places in this specification do not necessarily refer to the same embodiment, but may do so. Furthermore, the specific features, structures or properties can be combined in any suitable manner, as a person skilled in the art can see in this disclosure, in one or more embodiments. Although some embodiments described herein include some features but not others in other embodiments, combinations of features of different embodiments are intended to be within the scope of the invention and constitute different embodiments, as will be apparent to those skilled in the art. For example, in the following claims, any of the described embodiments may be used in any combination.

7 BE2022/5687

In the context of this document, a concrete frame building is a building with a frame that carries the load of the building. The framework comprises a network of concrete columns and concrete connecting beams that form the skeleton of the building. The concrete is usually reinforced concrete.

In the context of this document, reinforcing bars means reinforcing bars to strengthen concrete. These reinforcing bars can be in the form of bars, meshes, loops or combinations thereof.

In the context of this document, a corbel is a projection that extends from an element of a concrete frame, such as a support beam or a column, to support a structure above it.

In the context of this document, a stroke of a T-shape corresponds to the vertical part of the capital Roman letter T and an arm of a T-shape corresponds to the horizontal part of the Roman capital letter T on top of the stroke.

In a first aspect, the invention relates to a support beam for roof support of a concrete frame building.

Preferably, the support beam is formed by a concrete volume that extends in the longitudinal direction. The concrete volume is preferably reinforced with reinforcement. The concrete volume has a T-shaped cross-section in a plane perpendicular to the longitudinal direction. The T-shape is formed by a stroke and an arm. The support beam has a constant height. The height is measured perpendicular to the longitudinal direction and parallel to the direction of the stroke. A constant height is beneficial for obtaining a simple beam that is easy to produce and can be used or reused flexibly. Preferably, the T-shaped cross-section not only has a constant height, but the same dimension over the entire length of the support beam, the length of the support beam being measured in the longitudinal direction of the support beam.

The support beam comprises a volume of concrete reinforcement in each corner formed by the striking arm of the T-shape. When referring to the Roman capital letter

T, the angles mentioned are the 90° angles formed by the arm and the stroke to the left and right of the stroke. The reference to the Roman capital letter

T is for clarification purposes only and does not require that the actual angle between the

8 BE2022/5687 arm and the stroke of the support beam in the corners mentioned is exactly 90°. The actual angle may differ due to chamfers, for example. The concrete reinforcement volumes are limited by the stroke, the arm and a sloping wall. The angled wall extends from a free end of the arm to the stroke. The concrete reinforcement volume extends in the longitudinal direction of the support beam. The concrete reinforcement volume preferably extends in the longitudinal direction over the entire length of the support beam. It is clear to the skilled person that in this context the stroke and the arm do not mean a single line in a single cross-section perpendicular to the longitudinal direction of the support beam, but a surface defined by each stroke and arm in every possible cross-section perpendicular to the longitudinal direction. of the support beam. It is also clear that the arm-defined surface is an outer surface of the support beam corresponding to the top of the arm of a capital Roman letter T and that the stroke-defined surfaces are outer surfaces of the support beam corresponding to the left and right right side of the stroke of a capital Roman letter T. In the remainder of this document, stroke and arm can also refer to a single line in one cross-section or to a surface, depending on the context. The support beam has a low weight and high strength thanks to the T-shaped cross-section and the concrete reinforcement volumes in the corners formed by the stroke and arm of the T-shape.

The support beam includes a flat recess in the sloping wall at each end of the support beam and on both sides of the stroke. These ends of the support beam are defined along the length of the support beam. Accordingly, the support beam includes at least four flat recesses. The flat recesses define a flat surface. The flat recess is parallel to the arm. It is clear to the skilled person that it is meant that the flat surface defined by the flat recess is parallel to the surface defined by the arm, as explained earlier. A perforation runs from the flat recess through the arm. This means that the perforation starts on the flat surface defined by the flat recess and ends on the surface defined by the arm. The perforation therefore runs over the entire arm. The perforation runs parallel to the stroke. It is clear that the support beam includes at least four perforations, at least one for each flat recess.

The flat recesses are advantageous for releasably attaching the support beam to columns of a concrete skeleton of a building. The support beam is suitable for mounting on a flat surface defined by the arm of the T-shape

9 BE2022/5687 the columns or on corbels of the columns and be releasably attached to the columns through the perforations, such as bolts and nuts or threaded rods and nuts or threaded bushes and bolts, using connecting means. The flat recesses, parallel to the arm of the T-shape, allow the connectors to be tightened to securely attach the support beams to the columns. Because the support beam is provided with perforations on both sides of the stroke and because the support beam is suitable for being placed with the flat surface, defined by the arm of the T-shape, on the columns or on column corbels, the support beam suitable to absorb torsional forces in the longitudinal direction of the support beam. It is no longer necessary to attach the support beams in a non-detachable manner using, for example, mortar, cement or mortar to obtain a sturdy skeleton capable of absorbing the load on the skeleton, including the mentioned torsional forces . Because the support beams can be loosened by loosening the connecting means, it is possible to adapt a building's concrete frame if necessary or at least reuse the support beams when a building is demolished, greatly reducing the ecological footprint of a concrete frame building. The T-shape of the support beam is also advantageous because the support beam can be placed higher, through an upper surface formed by cross beams of a roof support of a concrete frame building, while maintaining the same strength as traditional I-shaped support beams. The same strength can be maintained because there is no need to reduce the height of the support beam to move the support higher. Traditional I-shaped support beams cannot protrude from that plane, reducing the useful stacking height in a warehouse, for example.

Preferably, the support beam includes a first looped reinforcement bar, a second looped reinforcement bar and a third looped reinforcement bar. The first, second and third looped reinforcing bars are preferably formed by bending a steel bar into a loop and welding the ends of the bent steel bar together. The first, second and third loop-shaped reinforcing bars extend in the longitudinal direction of the support beam. Preferably, the first, second and third loop-shaped reinforcing bars extend over at least 80% of the total length of the support beam in the longitudinal direction, preferably over at least 85% of the total length of the support beam, more preferably over at least 90%. % of the total length of the support beam and preferably over at least 95% of the total length of the support beam.

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The first looped reinforcing bar is placed in the support beam in a plane parallel to the strike. The second looped reinforcing bar and the third looped reinforcing bar are placed in the support beam in a plane parallel to the arm.

The second looped rebar and the third looped rebar are on either side of the strike.

This embodiment is advantageous to strengthen the concrete of the support beam against tensile forces in a direction parallel to the longitudinal direction and in the plane of the stroke (first looped reinforcing bar) or in a direction parallel to the longitudinal direction and in the plane of the arm (second and third reinforcing bar). Concrete can handle compressive forces well, but not tensile forces. The tensile forces are absorbed by the reinforcing bars. Due to the loop, the degree of pulling force is not important. This embodiment is also favorable because the support beam can be used in two directions, namely with the arm directed upwards or downwards.

Preferably, the support beam comprises a first series of looped reinforcing bars and a second series of looped reinforcing bars. A looped rebar is preferably formed by bending a steel bar into a loop and welding the ends of the bent steel bar together. Each looped reinforcing bar of the first series of looped reinforcing bars and each looped reinforcing bar of the second series of looped reinforcing bars is placed in a plane perpendicular to the longitudinal direction of the support beam. A looped reinforcing bar of the first series is placed in the stroke. A second series looped rebar is placed in the arm, or a second series looped rebar is placed in the arm and in the reinforcement volumes. A loop-shaped reinforcing bar of the second series preferably extends through a plane defined by the stroke.

This embodiment is advantageous to strengthen the concrete of the support beam against tensile forces in a direction perpendicular to the longitudinal direction and in the plane of the stroke (first series of looped reinforcement bars) or in a direction perpendicular to the longitudinal direction and in the plane of the arm ( second series of looped reinforcing bars).

A series of looped reinforcing bars is beneficial for good absorption of tensile forces in a direction perpendicular to the longitudinal direction over the entire length of the support beam. Because of the loop, the degree of force is not important. This embodiment is advantageously combined with the previous embodiment, to strengthen the concrete against tensile forces in directions parallel and perpendicular to the longitudinal direction of the support beam. This embodiment is favorable

11 BE2022/5687 combined with the previous embodiment, because it is possible to attach the first series and the second series of looped reinforcement bars to the first looped reinforcement bar, the second looped reinforcement bar and the third looped reinforcement bar, allowing the placement of the first and second series looped reinforcing bars during the casting of the support beam is simplified.

Preferably, the support beam comprises a third series of looped reinforcing bars. A looped rebar is preferably formed by bending a steel bar into a loop and welding the ends of the bent steel bar together.

Each looped reinforcing bar of the third series of looped reinforcing bars extends along the length of the support beam. Preferably, each looped reinforcing bar of the third series of looped reinforcing bars extends over at least 80% of the total length of the support beam in the longitudinal direction, preferably over at least 85% of the total length of the support beam, more preferably over at least 90% of the total length of the support beam and preferably over at least 95% of the total length of the support beam. Each looped rebar of the third series is parallel to the arm. Each looped reinforcing bar of the third series is placed within the support beam in a plane parallel to the arm. Each looped rebar of the third series of looped _ rebars is placed within the stroke.

This embodiment is advantageous to strengthen the concrete of the support beam against tensile forces in a direction parallel to the longitudinal direction and in the plane of the stroke. A series of looped reinforcing bars is beneficial to allow good absorption of tensile forces in a direction parallel to the longitudinal direction over the entire height of the support beam. Because of the loop, the meaning of the force is not important. This embodiment is advantageously combined with the two previous embodiments, to strengthen the concrete against tensile forces in directions parallel and perpendicular to the longitudinal direction of the support beam. This embodiment is advantageously combined with the previous embodiment describing the first looped reinforcing bar, because the third series of looped reinforcing bars can be attached to the first looped rebar, simplifying placement of the third series of looped rebars during support beam casting.

Preferably, the support beam comprises longitudinal reinforcement bars parallel to the longitudinal direction of the support beam. Preferably, a longitudinal reinforcing bar extends for at least 80% of the total length of the support beam

12 BE2022/5687 in the longitudinal direction, preferably over at least 85% of the total length of the support beam, more preferably over at least 90% of the total length of the support beam and preferably over at least 95% of the total length of the the support beam.

This embodiment is advantageous to strengthen the concrete of the support beam against tensile forces in a direction parallel to the longitudinal direction and in the striking surface. This embodiment is advantageous in combination with the three previously described embodiments.

Preferably the support beam comprises a corbel on both sides of the stroke. The corbels face each other and are placed lengthwise between the ends of the support beam. Preferably the corbels are equidistant from each end. If the support beam comprises multiple corbels on each side of the stroke, the corbels are preferably evenly distributed along the support beam, viewed in the longitudinal direction. A corbel comprises a cavity running parallel to the stroke in which connecting means can be placed.

The corbels on either side of the strike are advantageous for reducing the number of columns in a concrete frame building, while maintaining a sufficiently dense grid of support beams and transoms, creating more open space in the concrete frame building.

In a second aspect, the invention relates to a concrete skeleton building.

The concrete frame building preferably comprises at least four concrete columns, at least two supporting beams and at least two concrete cross beams. The support beams are concrete support beams. Preferably, the concrete columns, the support beams and the concrete cross beams are reinforced with reinforcement.

The concrete columns extend in a vertical direction. The concrete columns may include corbels to support the support beams and/or the cross beams. The concrete columns are mainly cylindrical or beam shaped or have another suitable shape. A column is preferably placed on a concrete slab or a concrete foundation.

The support beams are support beams according to the first aspect. The support beams are placed horizontally in a first direction between two concrete columns. The support beams rest directly on the concrete columns or on corbels of the concrete columns. The support beams are placed at each end of the support beam along the length of the support beam with the arm of the T-shape on the concrete column. The support beam has a low weight and high strength due to the...

T-shaped cross section and the volumes of concrete reinforcement in the corners formed by the stroke and arm of the T-shape. Because the support beam is provided with perforations on both sides of the stroke and because the support beam is suitable for being placed on the columns or on column corbels with the flat surface formed by the arm of the T-shape, the support beam is suitable to absorb torsional forces in the longitudinal direction of the support beam. It is not necessary to attach the support beams in a non-removable manner using, for example, mortar, cement or mortar to obtain a rigid skeleton that can withstand torsional forces around the longitudinal direction of the support beam.

At the same time, the support beam results in a reduced use of concrete for the construction of the concrete skeleton due to its T-shaped cross-section, which is beneficial for a smaller ecological footprint.

The cross beams are formed by a concrete volume that extends lengthwise. The concrete volume has a rectangular, I-shaped or

T-shaped cross section in a plane perpendicular to the longitudinal direction. The concrete volume preferably has a T-shaped cross-section. A crossbeam has a constant height. The height is measured perpendicular to the longitudinal direction. The cross beams are placed in a second direction between two concrete columns. The second direction is perpendicular to the first direction. Preferably, the second direction makes an angle of at most 10° with a plane determined by the support beams. Consequently, the second direction makes an angle of no more than 10° with a horizontal plane. The cross beams rest directly on the concrete columns or on corbels of the concrete columns.

The support beams and transverse beams provide roof support for the concrete frame building.

The support beams and cross beams are detachably attached to the concrete columns with connecting means. Non-limiting examples of suitable connecting means are bolts and nuts or threaded rods and nuts or threaded bushes and bolts. For example, a threaded rod can be cemented into an opening of the column. The threaded rod fits through a perforation in the support beam or cross beam. By tightening a nut, the support beam or cross beam is releasably attached to the concrete column. It is clear that the

14 BE2022/5687 support beam or cross beam can be detachably attached in a similar manner with bolts and nuts or threaded bushes and bolts. By attaching the support beams and cross beams to the concrete columns, an almost rectangular three-dimensional grid is obtained that forms the concrete skeleton of the concrete skeleton building.

The concrete frame building has the advantage that the concrete frame is formed by support beams and concrete cross beams that are detachably attached to the columns of the concrete frame, so that the concrete frame can be changed when the concrete frame building needs to be adapted to the changing needs of the users of the concrete frame building. At least the support beams and the concrete cross beams can be reused for the construction of the roof support of a new concrete frame building when the current building is demolished. The concrete frame building therefore results in a smaller ecological footprint.

In a further embodiment, a crossbeam has a T-shaped cross-section in a plane perpendicular to the longitudinal direction of the crossbeam. The T-shape is formed by a stroke and an arm. The crossbar stroke has a recess at each end of the crossbar running the length of the crossbar.

The concrete column is placed in the recess. A surface formed by the arm of the T-shape of the crossbeam faces upward. It is understood that the surface defined by the arm is an outer surface of the crossbeam corresponding to the top of the arm of a capital Roman letter T. At each end of the crossbeam is the surface defined by the arm of the T-shape of the crossbeam surface is at a lower height than a free end of the stroke of the T-shape of a support beam releasably attached to the same column. A free end of the travel of the crossbeam T-shape is located at each end of the crossbeam at the same height + 5.0 cm as a downward-facing surface formed by the arm of the supportbeam T-shape which is detachable attached to the same column. This free end of the stroke is preferably at the same height + 4.0 cm, preferably at the same height + 3.0 cm, and even more preferably at the same height + 2.0 cm. The height is measured in a vertical direction from a reference point on the column. Preferably, the cross beam has a length, measured in the longitudinal direction of the cross beam, that is greater than the length of the support beam, measured in the longitudinal direction of the support beam.

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This embodiment is especially advantageous for maximizing the available stacking height in an industrial building. A traditional roof construction of a concrete frame building leads to loss of height within the concrete frame building. Traditional roof construction includes support beams and transoms attached to concrete columns at varying heights.

This is a disadvantage, especially in the case of a warehouse, because the lowest point of the roof construction determines the permitted stacking height in the warehouse. In the current embodiment, the support beams form both the lowest and highest point of the roof of the building. The transoms form long spans of the roof between the support beams. Roof panels rest on the arms of the transoms. Roof panels are often corrugated sheets. Because the support beams are placed with the arms on the columns, the stroke of the support beams is directed upwards. The support beams are moved upwards relative to the traditional roof structure until the free end of the support beam stroke passes through an upper surface formed by the cross beams and until the free end of the cross beam T-shape stroke is at each end of the crossbeam is at the same height + 5.0 cm as the downward-facing surface formed by the arm of the T-shape of the support beam. The available height within the concrete frame building is therefore maximum.

In another embodiment, the support beams comprise a corbel on either side of the stroke of the support beam.

The corbels are opposite each other and are placed between the ends of the support beam along the length of the support beam. Preferably the corbels are equidistant from each end. If the support beam comprises multiple corbels on each side of the support beam, the corbels are preferably regularly distributed along the support beam, viewed in the longitudinal direction. A corbel comprises a cavity parallel to the stroke in which connecting means can be accommodated.

Additional cross beams are placed in the second direction between two adjacent support beams. The additional cross beams are identical to the cross beams placed in the second direction between two concrete columns. This is beneficial for simplifying the construction of the concrete frame building and also for the reuse of the additional cross beams after demolition of the concrete frame building in the construction of a new concrete frame building. The additional crossbeams can be detached from the corbels using connecting means

16 BE2022/5687 of the adjacent support beams. Non-limiting examples of suitable connecting means are bolts and nuts or threaded rods and nuts or threaded bushes and bolts.

The corbels on either side of the support beams and the additional cross beams are beneficial in reducing the number of columns in a concrete frame building, while maintaining a sufficiently dense grid of support beams and cross beams, creating more open space in the concrete frame building.

A surface formed by the arm of the T-shape of the additional crossbeam faces upwards. At each end of the additional crossbeam this surface is at a lower height than a free end of the stroke of the T-shape of the support beam to which it is releasably attached. A free end of the stroke of the auxiliary crossbar T-shape is located at each end of the crossbar at the same height + 5.0 cm as a downward-facing surface formed by the arm of the T-shape of the support beam to which this end is detachably attached. This free end of the stroke is preferably at the same height + 4.0 cm, preferably at the same height + 3.0 cm, and even more preferably at the same height + 2.0 cm. The height is measured in the vertical direction from the reference point mentioned in the previous embodiment.

This embodiment has the same advantages for maximizing the available stacking height.

Corrugated sheets are preferably placed on the support beams and cross beams as roofing. The corrugated sheets are preferably metal corrugated sheets. The free end of the stroke of each support beam is placed in a groove of a corrugated sheet. That free end of the stroke has a profile that is a maximum of 1 cm away from the walls of the corrugated sheet that forms the groove.

This embodiment has the advantage that the support beam can protrude through the top surface formed by the cross beams as described earlier, while the corrugated sheets can still be placed uninterruptedly, as in a traditional roof construction. There is no need to create a roof ridge, which would increase effort and costs and increase the risk of leaks. It is clear that this embodiment can also be used for additional crossbeams. This embodiment can be advantageously combined with the two previously described embodiments to maximize the stacking height.

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Preferably, an elastomer block is placed under the cross beams of the concrete skeleton. The elastomer block is placed between the transoms and the columns or between the transoms and the collars of the columns on which the transoms rest. The elastomer block has a density of at least 1200 kg/m3, preferably a density of at least 1300 kg/m3?, preferably a density of at least 1400 kg/m3? and preferably a density of at least 1500 kg/m3. The elastomer block has a tensile strength of at least 2.5

MPa, preferably a tensile strength of at least 3.0 MPa, preferably a tensile strength of at least 3.5 MPa and preferably a tensile strength of 4.0 MPa.

The tensile strength is determined according to ISO 37:2017. The elastomer block has an elongation at break of at least 150%, preferably at least 160%, preferably at least 170% and preferably at least 180%. The elongation at break is determined according to ISO 37:2017. The elastomer block has a Shore A hardness of at least 40, preferably at least 50 and preferably at least 60. A non-limiting example of a suitable material for the elastomer block is a synthetic rubber such as neoprene.

A concrete skeleton with removable crossbeams allows small movements of the crossbeams relative to the columns. To prevent damage due to friction or breakage of the crossbeams or columns, elastomer blocks are placed under the crossbeams to allow these small movements. However, the elastomer block must be able to withstand the enormous loads of the concrete skeleton building. An elastomer block with the aforementioned properties can withstand the required load without excessive or premature wear.

The elastomer block may be located under the support beams. The elastomer block has the same advantages.

This embodiment is also advantageous in combination with the previously described additional cross beams, in which case the elastomer block is placed between the additional cross beams and the corbels of the support beams.

Furthermore, the elastomer block has an upper surface and a lower surface, the upper surface and the lower surface being at an angle of at least 1° and at most 10°. Preferably the angle is at most 8°, preferably at most 6°, more preferably at most 4° and preferably at most 3°.

This embodiment is advantageous for the construction of the roof support of a concrete frame building with standardized and identical cross beams.

This roof support should be sloped to facilitate drainage of water on the roof. Therefore, the transoms are usually shaped differently from transoms of other levels of the concrete frame building to achieve the required slope. Usually these crossbars have a triangular shape.

Depending on the slope required, a different shape of crossbeam must be manufactured. The required slope for the roof support is obtained by placing the elastomer blocks under the cross beams, which have an angle between the upper surface and the lower surface corresponding to the required slope.

Identical cross beams can be used regardless of the slope, reducing costs and simplifying the design and construction of the concrete frame building. A small angle between 1° and 10° is sufficient for the drainage of water on the roof. Such a small angle also requires only a very small space between the column and the crossbeams for the crossbeams to slope.

It is clear that this embodiment is also advantageous in combination with additional cross beams described earlier.

Preferably, the support beams have equal lengths measured in the longitudinal direction of the support beams and the cross beams have equal lengths measured in the longitudinal direction of the cross beams. The length of the support beams can be different or equal to the length of the cross beams. Due to the equal lengths of the support beams and the equal lengths of the cross beams, a completely regular grid is obtained for the concrete skeleton.

This embodiment is favorable for simplifying the construction of the concrete frame building. Each support beam can be used for any position of a support beam in the concrete frame building and each cross beam can be used for any position of a cross beam in the concrete frame building. This embodiment is also beneficial for reducing construction costs because the support beams and cross beams can be produced in larger numbers. This embodiment is especially beneficial for the reuse of support beams and transoms when a concrete frame building is demolished, because a new building can be designed to use standard length support beams and transoms.

In a third aspect, the invention relates to a method for the construction of a concrete frame building.

Preferably the method includes the steps of: — placing at least four concrete columns on a rectangular grid; — placing support beams in a first direction horizontally between each pair of concrete columns; — attaching the support beams to the concrete columns; — placing cross beams in a second direction between each pair of concrete columns; — attaching the cross beams to the concrete columns.

The support beams and cross beams are concrete support beams and cross beams. Preferably, the concrete columns, the support beams and the concrete cross beams are reinforced with reinforcement. The support beams and cross beams provide roof support for the concrete frame building.

The concrete columns extend in a vertical direction. A column is preferably placed on a concrete slab or a concrete foundation.

The support beams are support beams according to the first aspect. The support beams are placed at each end of the support beam along the length of the support beam with the arm of the T-shape on the concrete column. As previously described, it is not necessary to attach the support beams in a non-detachable manner with, for example, mortar, cement or mortar to obtain a sturdy skeleton that can withstand torsional forces around the longitudinal direction of the support beam, allowing the concrete skeleton of the building to be whether the support beams can be reused. At the same time, the reduced use of concrete for the construction of the concrete skeleton is beneficial for a smaller ecological footprint.

The sleepers are formed by a concrete volume that extends lengthwise. The concrete volume has a rectangular, I-shaped or - T-shaped cross-section in a plane perpendicular to the longitudinal direction. The concrete volume preferably has a T-shaped cross-section. A crossbeam has a constant height. The height is measured perpendicular to the longitudinal direction. The second direction is perpendicular to the first direction. Preferably, the second direction makes an angle of at most 10° with a plane determined by the support beams.

The support beams and cross beams are detachably attached to the concrete columns with connecting means. Non-limiting examples of suitable connecting means are bolts and nuts or threaded rods and nuts or threaded bushes and bolts.

The method is advantageous for the construction of a concrete frame building that can be adapted to the changing needs of the users of the concrete frame building or that at least allows the reuse of support beams and transoms for the construction of a new concrete frame building when the building is demolished. The method reduces the ecological footprint of the construction of a concrete frame building.

It is clear to a person skilled in the art that some steps of the method can be performed in a different order or that a step does not need to be completely completed before the execution of a subsequent step begins.

For example, it is possible to start placing a support beam or a cross beam after placing two concrete columns. It is also possible that after placing some support beams, some cross beams are already placed, while people continue to place concrete columns.

Preferably, the support beams comprise a corbel on either side of the stroke of the support beam.

The corbels are opposite each other and are placed between the ends of the support beam along the length of the support beam. Preferably the corbels are equidistant from each end. A corbel comprises a cavity running parallel to the stroke for receiving connecting means.

The method includes an additional step in which additional cross beams are placed in the second direction between two adjacent support beams and the additional cross beams are releasably attached to the corbels of the adjacent support beams with connecting means. This additional step is beneficial to reduce the number of columns in a concrete frame building, while maintaining a sufficiently dense grid of support beams and transoms, resulting in more open space in the concrete frame building.

Preferably, the method also includes the placement of an elastomer block under the transverse beams of the concrete frame of the concrete frame building. The elastomer block has a density of at least 1200 kg/m3, preferably a density of at least 1300 kg/m3, preferably a density of at least 1400 kg/m3. and preferably a density of at least 1500 kg/m3. The elastomer block has a tensile strength of at least 2.5 MPa, preferably a tensile strength of at least 3.0 MPa, preferably a tensile strength of at least 3.5 MPa and preferably a tensile strength of 4.0 MPa. The tensile strength is determined according to ISO 37:2017. The elastomer block has an elongation at break of at least 150%, preferably at least 160%, preferably at least 170% and preferably at least 180%. The elongation at break is determined according to ISO 37:2017. The elastomer block has a Shore

A hardness of at least 40, preferably at least 50 and preferably at least 60. A non-limiting example of a suitable material for the elastomer block is a synthetic rubber such as neoprene. An elastomeric block with these properties can withstand the load of the concrete frame building without excessive or premature wear and prevents damage or breakage of transoms or columns due to small movements between the transoms and the columns.

If necessary, the elastomer block is also placed under the support beams. This embodiment is also advantageous in combination with additional cross beams described earlier.

Furthermore, the elastomer block has an upper surface and a lower surface, the upper surface and the lower surface being at an angle of at least 1° and at most 10°. Preferably the angle is at most 8°, preferably at most 6°, more preferably at most 4° and preferably at most 3°.

This embodiment is advantageous for the construction of the roof support of a concrete frame building with standardized and identical cross beams. The required slope for the roof support to facilitate the drainage of water on the roof is obtained by placing the elastomer blocks under the cross beams, which have an angle between the upper surface and the lower surface corresponding to the required slope. Identical cross beams can be used regardless of the required slope, reducing costs and simplifying the design and construction of the concrete frame building.

An ordinary skilled person will understand that a support beam according to the first aspect is suitable for the construction of a concrete frame building according to the second aspect and for the implementation of a method according to the third aspect, that a concrete frame building according to the second aspect is preferably constructed using support beams according to the first aspect and the method according to the third aspect and that a method according to the third aspect is preferably carried out using support beams according to the first aspect and is preferably carried out for the construction of a concrete frame building according to the second aspect. Accordingly, any feature described in this document, both above and below, may relate to any of the three aspects of this invention.

The invention is further described by the following non-limiting figures which further illustrate the invention, and which are not intended to limit the scope of the invention and should not be construed as such.

DESCRIPTION OF THE FIGURES

Figure 1 shows a top view of a roof support of a prior art concrete frame building.

The concrete skeleton building is composed of columns (42), support beams (1), transverse beams (23) and additional transverse beams (47). The support beams (1) are not according to the present invention. The support beams (1) have an I-shaped cross-section.

The support beams (1) are placed on corbels (7) of the columns (42). The cross beams (23) are not according to the present invention. The cross beams (23) have an I-shaped cross-section. The cross beams (23) are placed on the columns (42). The additional cross beams (47) are not according to the present invention.

The additional cross beams (47) have an I-shaped cross-section. The additional cross beams (47) are not identical to the cross beams (23). The additional cross beams (47) have a recess for receiving the collar stone (7) of the support beams (1). The additional cross beams (47) and the cross beams (23) have different lengths. The cross beams (23) have a lower surface located at one end of the cross beam (23) attached to the column (42) at a higher height than a lower surface of the support beam (1) attached to the same column (1). confirmed. The additional cross beams (47) have a bottom surface attached to one end of the additional cross beam (47) attached to the support beam collar stone (7).

(1) is attached, is at a greater height than a bottom surface of the same support beam (1).

Figure 2 shows a side view of a support beam according to an embodiment of this invention.

The support beam (1) is formed by a concrete volume that extends in the longitudinal direction (8). The concrete volume has a T-shaped cross-section in a plane perpendicular to the longitudinal direction (8). The T-shaped cross section will be clearly visible in Figures 3A and 3B. The T-shape is formed by a stroke (6) and an arm (2). The stroke (6) and arm (2) will also be clearly visible in Figures 3A and 3B. The support beam (1) has a constant height (10). The height (10) is measured perpendicular to the longitudinal direction (8) and parallel to the stroke (6). The support beam (1) includes a concrete reinforcement volume (3) in each corner formed by the stroke (6) and the arm (2).

The concrete reinforcement volume (3) is limited by the stroke (6), the arm (2) and an inclined wall (11). This is clearly shown in Figure 3B. The support beam (1) comprises a flat recess (4) in the sloping wall (11) at each end (9) of the support beam (1) and on either side of the stroke (6). A perforation (5) runs from the flat recess (4) through the arm (2). The perforation (5) runs parallel to the stroke (6). The support beam (1) includes a collar (7) on both sides of the stroke (6). The collar (7) is shown in more detail in Figure 4.

Figure 3A shows a section along axis A-A of the support beam of Figure 2.

Figure 3A clearly shows that the flat recess (4) defines a flat surface parallel to the arm (2) and that on each side of the stroke (6) there is a perforation (5) through the arm (2) parallel to the stroke ( 6) runs. The support beam (1) comprises a first looped reinforcement bar (12), a second looped reinforcement bar (13) and a third looped reinforcement bar (14), which extends in the longitudinal direction (8) of the support beam (1). The first looped reinforcing bar (12) is placed within the support beam (1) in a plane parallel to the stroke (6). The second looped reinforcement bar (13) and the third looped reinforcement bar (14) are placed in the support beam (1) in a plane parallel to the arm (2). The second looped rebar (13) and the third looped rebar (14) are on either side of the stroke (6). The support beam (1) includes a first series of looped reinforcing bars (15), a second series of looped reinforcing bars (16) and a third series of looped reinforcing bars (17). Each looped reinforcing bar of the first series of looped reinforcing bars (15) and each looped reinforcing bar of the second series of looped reinforcing bars (16) is placed in a plane perpendicular to the longitudinal direction (8) of the support beam (1). A looped reinforcing bar of the first series (15) is placed in the stroke (6). A looped reinforcing bar of the second series (16) is placed in the arm (2) and extends through a plane defined by the stroke (6). Each looped reinforcing bar of the third series (17) extends in the longitudinal direction (8) of the support beam. Each looped rebar of the third series (17) is parallel to the arm (2) and positioned within the stroke (6). The support beam (1) further comprises longitudinal reinforcement bars (18) that are parallel to the longitudinal direction (8) of the support beam (1).

Figure 3B shows a section along axis B-B of the support beam of Figure 2.

Figure 3B shows how the concrete reinforcement volume (3) is limited by the stroke (6), the arm (2) and an inclined wall (11). The sloping wall (11) extends from a free end of the arm (2) to the stroke (6). In this part of the support beam (1), where there is no flat recess (4), a looped reinforcement bar of the second series (16) is placed in the arm (2) and in the reinforcement volume (3).

Figure 4 shows a detail of a section along the axis C-C of the support beam of Figure 2.

Figure 4 does not show the full length of the support beam (1) of figure 2, but only the part near the corbels (7). Figure 4 clearly shows that the support beam (1) comprises a corbel (7) on either side of the stroke (6). The corbels (7) are opposite each other with respect to the strike (6). Each corbel (7) includes a cavity (22) extending parallel to the strike (6) into which fasteners can be placed. The corbels (7) include a first looped reinforcing bar (19) to strengthen the concrete against tensile forces in directions parallel to the arm (2) and perpendicular to the longitudinal direction (8). The corbels (7) comprise a first series of looped reinforcing bars (20) to strengthen the concrete against tensile forces in directions parallel to the stroke (6) and perpendicular to the longitudinal direction (8). The corbels (7) include a second series of looped reinforcing bars (21) to strengthen the concrete against tensile forces in directions perpendicular to the longitudinal direction (8) and parallel to the arm (2).

Figure 5 shows a side view of a crossbeam according to an embodiment of this invention.

The crossbeam (23) is formed by a concrete volume that extends in the longitudinal direction (30).

The concrete volume has a T-shaped cross-section in a plane perpendicular to the longitudinal direction (30). The T-shaped cross-section will be clearly visible in Figures 6A, 6B, 6C and 6D. The T-shape is formed by a stroke (25) and an arm (24). The stroke (25) and arm (24) will also be clearly visible in Figures 6A, 6B, 6C and 6D. The crossbar (23) has a constant height (31). The height (31) is measured perpendicular to the longitudinal direction (30) and parallel to the stroke (25). The stroke (25) of the crossbar (23) has a recess (28) at each end (26) of the crossbar (23) along the longitudinal direction (30) of the crossbar (23). The crossbar (23) has a perforation (27) at each end (26). The perforation (27) runs parallel to the stroke (25) through the cross beam (23). At one end (26) of the crossbar there is a cylindrical passage (29) through the stroke (25). The passage (29) has an axis parallel to the arm (24) and perpendicular to the longitudinal direction (30). The passage (29) is useful as a passage for pipes, cables and the like.

Figure GA shows a section along axis A-A of the crossbeam of Figure 5.

Figure 6A clearly shows how the perforation (27) runs parallel to the stroke (25) through the cross beam (23). The cross beam (23) comprises longitudinal reinforcing bars (32) in the longitudinal direction (30) to strengthen the concrete against tensile forces in directions parallel to the longitudinal direction (30). The cross beam (23) includes a first looped reinforcement bar (33) extending in the longitudinal direction (30) to strengthen the concrete against tensile forces in directions parallel to the longitudinal direction (30). The crossbeam (23) includes a first series of looped reinforcing bars (34) running longitudinally (30) and parallel to the arm (24) to strengthen the concrete against tensile forces in directions parallel to the longitudinal direction (30). The cross beam (23) comprises a second series of looped reinforcement bars (35) placed in a plane perpendicular to the longitudinal direction (30). The second series (35) is placed in the arm (24). The cross beam (23) includes a third series of looped reinforcing bars (36) lying in a plane perpendicular to the longitudinal direction (30). The third series (36) is placed in the arm (24) and the stroke (25). When comparing Figure 6A with Figures 6B, 6C and 6D, it is clear that part of the stroke (25) is missing due to the recess (28).

Figure GB shows a section along axis B-B of the cross beam of Figure 5.

Figure 6B clearly shows that the crossbar (23) between the two ends (26) comprises a fourth series of looped reinforcement bars (37) and a fifth series of looped reinforcement bars (38) to strengthen the stroke (25). The looped reinforcing bars of the fourth series (37) extend in the longitudinal direction (30) and are placed in the stroke (25) and the arm (24). The looped reinforcement bars of the fifth series (38) extend longitudinally (30) and parallel to the arm (24) to strengthen the concrete against tensile forces in directions parallel to the longitudinal direction (30). Note that the dimensions of the third series looped reinforcing bars (36) have changed due to the changed dimensions of the stroke (25).

Figure 6C shows a section along axis C-C of the crossbeam of Figure 5.

The reinforcements remain the same as in Figure 6D.

Figure 6D shows a section along axis D-D of the crossbeam of Figure 5.

The third series (36) is locally interrupted by the passage (29). A second looped reinforcing bar (39) strengthens a lower part of the stroke (25) instead.

Figure 7 shows a detail of a side view of a concrete skeleton according to an embodiment of this invention.

The support beam (1) is placed on a concrete column (42). The support beam (1) is similar to the support beam (1) in Figure 1. The column (42) extends in the vertical direction. The arm (2) of the support beam (1) is placed at the end (9) of the support beam (1) on a first horizontal surface (44) of the column (42). Threaded rods (41) extend from the first horizontal surface (44) and pass through the perforations (5). The support beam (1) is detachably attached to the column (42) by tightening a nut (40) on the threaded rod (41). The column (42) has a second horizontal surface (45) above the first horizontal surface (44). The cross beam (23) is placed on the concrete column (42).

placed. The crossbar (23) is similar to the crossbar (23) in Figure 4. The stroke (25) of the crossbar (23) is attached to the end (26) of the crossbar (23) on the second horizontal surface (45) of the the column (42) is placed. A threaded rod (41) extends from the second horizontal surface (45) and extends through the perforation (27) and an elastomer block (43). At the end (26) of the cross beam (23), an upwardly directed surface formed by the arm (24) of the cross beam (23) is located at a lower height than a free end of the stroke (6) of the support beam ( 1). A free end of the stroke (25) of the crossbar (23) is located at the end (26) of the crossbar (23) at the same height + 2.0 cm as a downward facing surface formed by the arm (2) of the support beam (1). Corrugated plates (46) are placed on the support beam (1) and the cross beam (23). The free end of the stroke (6) of the support beam is placed in a groove (47) of the corrugated plate (46). The free end of the stroke (6) has a profile that is a maximum of 1 cm away from the walls of the corrugated roof panel (46) that form the groove (47). The elastomer block (43) is placed between the cross beam (23) and the column (42). The elastomer block (43) has a top and a bottom. The cross beam (23) lies on the top surface and the elastomer block (43) lies with its bottom surface on the second horizontal plane (45). The top surface and bottom surface of the elastomer block (43) are at an angle of 2°. This causes a 2° inclination of the cross beam (23) with respect to a horizontal plane. The cross beam (23) is detachably attached to the column (42) by tightening a nut (40) on the threaded rod (41).

The numbers refer to: 1. Support beam 2. Arm of support beam 3. Reinforcement volume 4. Flat recess 5. Perforation in support beam 6. Stroke of support beam 7. Corbel 8. Longitudinal direction of support beam 9. End of support beam 10. Height of support beam 11. Slanted wall 12. First loop of the support beam 13. Second loop of the support beam 14. Third loop of the support beam

15. First series of looped rebars of girder 16. Second series of looped rebars of girder 17. Third series of looped rebars of girder 18. longitudinal rebars of girder 19. First loop in the crossbeam reinforcement

20. First series of looped corbel reinforcing bars 21. Second series of looped corbel reinforcing bars 22. Cavity 23. Sleeper

24. Arm of cross beam 25. Stroke of cross beam 26. End of cross beam 27. Perforation in cross beam 28. Cut out

29. Passage 30. Longitudinal direction of crossbeam 31. Height of crossbeam 32. longitudinal rebars of crossbeam 33. First looped rebars of crossbeam

34, First series of looped cross beam reinforcing bars 35. Second series of looped cross beam reinforcing bars 36. Third series of looped cross beam reinforcing bars 37. Fourth series of looped cross beam reinforcing bars 38. Fifth series of looped cross beam reinforcing bars

39, Second looped cross beam reinforcement bars 40. Nut 41. Threaded rod 42. Column 43. Elastomeric block

44. First horizontal surface 45, Second horizontal surface 46. Corrugated sheets 47. Additional cross beams

Claims (16)

CONCLUSIONS 1. Support beam for roof support of a concrete frame building, wherein the support beam is formed by a concrete volume extending in the longitudinal direction, wherein the supporting beam has a constant height, wherein the concrete volume has a T-shaped cross-section in a plane perpendicular to the longitudinal direction, wherein the T-shape is formed by a stroke and an arm, where the support beam comprises a concrete reinforcement volume at each corner formed by the stroke and the arm of the T-shape, where the concrete reinforcement volumes are bounded by the stroke, the arm and a sloping wall extending from a free end of the arm to the stroke, characterized in that the support beam comprises a flat recess in the sloping wall at each end of the support beam along the length and on both sides of the stroke, wherein the flat recess is parallel to the arm, with a perforation parallel to the stroke running from the flat recess through the arm. 2. Support beam according to claim 1, characterized in that the support beam comprises a first looped reinforcement bar, a second looped reinforcement bar and a third looped reinforcement bar, wherein the first, second and third looped reinforcement bar extend in the longitudinal direction of the support beam, wherein the first looped reinforcing bar is placed in a plane parallel to the stroke, with the second and third looped reinforcing bar being placed in a plane parallel to the arm and with the second and third looped reinforcing bar being placed on either side of the stroke. 3. Support beam according to claim 1 or 2, characterized in that the support beam comprises a first series of looped reinforcement bars and a second series of looped reinforcement bars, wherein each looped reinforcement bar of the first series and the second series of looped reinforcement bars is placed in a plane perpendicular to the longitudinal direction of the support beam, where a looped reinforcement bar of the first series is placed in the stroke and where a looped reinforcement bar of the second series is placed in the arm or in the arm and the reinforcement volumes. 4. Support beam according to any one of the preceding claims 1 to 3, characterized in that the support beam comprises a third series of looped reinforcement bars, wherein each looped reinforcement bar of the third series of looped reinforcement bars extends in the longitudinal direction of the support beam, with each looped reinforcement bar of the third series of looped reinforcing bars is parallel to the arm, and a looped reinforcing bar of the third series is placed in the stroke. A support beam according to any one of the preceding claims 1 to 4, characterized in that the support beam comprises longitudinal reinforcement bars that are parallel to the longitudinal direction of the support beam. 6. Support beam according to any one of the preceding claims 1 to 5, characterized in that the support beam comprises a corbel on either side of the stroke, wherein the corbels lie opposite each other and are located between the ends of the support beam in the longitudinal direction and wherein a corbel comprises a cavity running parallel to the stroke for receiving connecting means. 7. Concrete frame building comprising at least four concrete columns, at least two supporting beams and at least two concrete transverse beams, wherein the concrete columns extend in a vertical direction, wherein the supporting beams are placed horizontally in a first direction between two concrete columns, wherein the transverse beams are formed by a concrete volume extending in the longitudinal direction, wherein the transverse beams have a constant height, wherein the transverse beams are placed in a second direction between two concrete columns, wherein the second direction is transverse to the first direction, and wherein the supporting beams and the cross beams form a roof support, characterized in that the support beams comply with one of the preceding claims 1 to 6, wherein the support beams are located at each end of the support beam in the longitudinal direction of the support beam with the arm of the T-shape on the concrete column have been placed and the supporting beams and cross beams are detachably attached to the concrete columns using connecting means. 8. Concrete frame building according to claim 7, characterized by a transverse beam with a T-shaped cross-section perpendicular to the longitudinal direction of the transverse beam, wherein the T-shape is formed by a stroke and an arm, wherein the stroke of the transverse beam is at each end of the transverse beam has a recess along the longitudinal direction of the transverse beam, the column being received in the recess, with a surface formed by the arm of the T-shape of the transverse beam pointing upwards, this surface being located at each end of the transverse beam at a lower height than a free end of the stroke of the T-shape of a support beam releasably attached to the same column and with a free end of the stroke of the T-shape of the cross beam located at each end of the beam at the same height + 5.0 cm as a downward-facing surface formed by the arm of the T-shape of the support beam detachably attached to the same column. 9. Concrete frame building according to claim 8, characterized in that the support beams comprise a corbel on both sides of the stroke of the support beam, wherein the corbels lie opposite each other and are placed between the ends of the support beam in the longitudinal direction of the support beam, wherein a corbel comprises a perforation that runs parallel to the stroke through the corbel, wherein additional crossbeams are placed in the second direction between two adjacent support beams, wherein the extra crossbeams are identical to the crossbeams, wherein the extra crossbeams can be detached with connecting means from the corbels of the adjacent support beams are fixed, with a surface formed by the arm of the T-shape of the additional cross beam pointing upwards, at each end of the additional cross beam this surface being at a lower height than a free end of the stroke of the T-shape of the support beam to which this end is detachably attached and whereby a free end of the stroke of the T-shape of the additional cross beam is located at each end of the cross beam at the same height + 5.0 cm as a downward-facing surface formed by the arm of the T-shape of the support beam to which this end is detachably attached. 10. Concrete frame building according to any of the preceding claims 7 to 9, characterized in that corrugated sheets are placed on the supporting beams and transverse beams as roof covering, wherein the free end of the stroke of each supporting beam is placed in a groove of a corrugated sheet and wherein the free end of the stroke has a profile that is no more than 1 cm away from the walls of the corrugated sheet that forms the groove. 11. Concrete frame building according to any of the preceding claims 7 to 10, characterized in that an elastomer block is placed under the transverse beams of the concrete frame, wherein the elastomer has a density of at least 1200 kg/m2, a tensile strength of at least 2 .5 MPa, an elongation at break of at least 150% and a Shore A hardness of at least 40. 12. Concrete frame building according to claim 11, characterized in that the elastomer block has an upper surface and a lower surface, wherein the upper surface and the lower surface lie at an angle of at least 1° and at most 10°. 13. Concrete frame building according to any of the preceding claims 7 to 12, characterized in that all support beams are the same length measured in the longitudinal direction of the support beams and all cross beams are the same length measured in the longitudinal direction of the cross beams. 14. Method for the construction of a concrete frame building, comprising the steps of: — placing at least four concrete columns on a rectangular grid, the concrete columns extending in a vertical direction; — placing support beams in a first direction horizontally between each pair of concrete columns; — attaching the support beams to the concrete columns; — placing transverse beams in a second direction between each pair of concrete columns, the transverse beams being formed by a concrete volume extending in the longitudinal direction, the transverse beams having a constant height and the second direction being transverse to the first direction; — attaching the cross beams to the concrete columns; characterized in that the support beams comply with any of the preceding claims 1 to 6, wherein the support beams are placed at each end of the support beam in the longitudinal direction of the support beam with the arm of the T-shape on the concrete column and wherein the support beams and the cross beams are detachably attached to the concrete columns with connecting means. 15. Method according to claim 14, characterized in that the support beams comprise a corbel on both sides of the stroke of the support beam, the corbels being opposite each other and placed between the ends of the support beam in the longitudinal direction of the support beam, wherein a corbel comprises a cavity extending parallel to the strike for the reception of connecting means, the method comprising an additional step in which additional cross beams are placed in the second direction between two adjacent support beams and the additional cross beams are releasably attached to the corbels with connecting means of the adjacent support beams. 16. Method according to claim 14 or 15, characterized in that the method includes an additional step of placing an elastomer block under the transverse beams of the concrete skeleton, wherein the elastomer has a density of at least 1200 kg/m3, a tensile strength of at least 2.5 MPa, an elongation at break of at least 150% and a Shore A hardness of at least 40, where the elastomeric block has an upper surface and a lower surface, and where the upper surface and the lower surface are inclined at an angle of at least 1° and a maximum of 10°.