PL248675B1 - Wooden structural beam - Google Patents

Abstract

The subject of the application is a wooden structural beam with curved undercuts and a steel tie, freely supported, for use in construction, especially as a girder structural element. A wooden structural beam made of glued laminated timber is characterized in that along the wooden structural beam (1) there are at least three transverse curved cutouts (5) arranged symmetrically with respect to the vertical axis of symmetry of the beam and at least two ribs (4) which are located between the transverse curved cutouts (5), wherein the transverse curved cutouts (5) have an elliptical or circular shape with the length of: chord a, which has a length from 0.75 m to 1.25 m and arrow h, which has a height from 1/4 to 1/3 of the total height of the beam (1) H, wherein the height H of the beam (1) is the number n of lamellas with a single height c and H is within the range from 0.8 m to 1.4 m.

Description

The subject of the invention is a wooden structural beam with curved undercuts and a steel tie, freely supported, for use in construction, especially as a girder structural element.

STATE OF THE ART

There are various types of girder beams with different material properties and various cross-sections and longitudinal shapes. Wooden girder beams, obtained by joining pieces of wood, occupy a special place here.

Polish patent description PL.162908 describes a layered-shaped construction beam made of fiber cement. The structural concept is similar to the internal structure of wood. The construction beam is composed of a hollow core, constructed of sections with walls made of nonwoven fabric with a cement shell, enclosing inner grains that bind the nonwoven fabric to the cement shell. Between the layers and the central grains are supporting tendons in the form of fiber ropes with a cement shell in concrete strips. The ropes are prestressed, which allows for balancing the beam's permissible operating loads.

The description of utility model Ru.053930 describes openwork beams characterized by a lower center of gravity. The beams consist of two parts, the lower part of which, stretched during operation, has a cross-sectional area greater than the upper part, which is compressed or stretched less during operation. The beams are created by cutting two I-beams along a broken line with the same geometric characteristics for both I-beams, and then combining them to create openings between them.

Dutch patent application NL8203471A describes a beam made of standard-sized wood, with a single rod placed in each opposing plane in the compression and tension zones along the beam. A steel rod is placed in each slot, or a cord or textile string is placed in the slot adjacent to the compression zone as reinforcement, embedded in a hardened polymer material adjacent to the reinforcement and the slot wall. The beam is anchored in a curved position in the compression zone under the influence of the reinforcement, creating a bend.

Australian patent specification AU2022202080B1 discloses a structural beam comprising a laminated wood laminate in combination with stiffening elements that allow for a higher structural standard for the wood laminate. In one embodiment, the wood laminate beam comprises glued wood layers with a generally oval transverse shape and longitudinal length, the transverse shape comprising relatively shorter width sides and longer depth sides. The shorter width sides of the wood laminate beam have elongated recesses, and stiffening elements are positioned and glued within these elongated recesses in the wood laminate beam. The method of manufacturing comprises providing a wood laminate beam, forming at least one elongated recess in the shorter width side or sides of the wood laminate beam, and positioning and gluing at least one stiffening element within the at least one elongated recess.

US patent application US2003029128A1 describes a wooden beam composed of several sections that are subjected to transverse stress, particularly in areas with recesses or openings. The beam uses rod-shaped elements, such as screws, that extend transversely to the beam's longitudinal direction to absorb this transverse stress. These screws are screwed into the beam from the top or bottom, and each screw extends only through a portion of the beam's height (H), which directly relates to the area subjected to transverse stress.

Previous solutions, when using channels for installations such as electrical or ventilation, significantly deteriorate the mechanical properties of the beam.

DISCLOSURE OF INVENTION

The technical problem solved by the invention is the routing of installation cables in a beam made of glued wood, while maintaining its dimensions and load-bearing capacity, which is achieved thanks to curvilinear cutouts along the beam, made in the tensile zone, and the use of a steel tie made of flat bar below the cutouts.

In the light of the described prior art, the aim of the present invention is to overcome the indicated disadvantages and provide a beam with a load-bearing capacity similar to the value obtained for a beam without cutouts of the same dimensions, which is achieved by using curvilinear cutouts and reinforcements in the form of metal elements located at the lower edge of the beam fastened with pin elements.

A wooden structural beam according to the invention, constructed of segments in the form of longitudinal lamellas of glued wood, equipped with reinforcing elements in the tension zone in the form of pin elements and flat bars of structural steel, intended for use as a girder element in construction, is characterized in that along the wooden structural beam there are at least three transverse curvilinear cutouts arranged symmetrically with respect to the vertical axis of symmetry of the beam and at least two ribs which are located between the transverse curvilinear cutouts, wherein the transverse curvilinear cutouts have an elliptical or circular shape with the dimensions: - chord a, which has a length of 0.75 m to 1.25 m and

- arrow h, which has dimensions from 1/4 to 1/3 of the total height of the beam H, where the height H of the beam is the number n of lamellas with a single height c and H is in the range from 0.8 m to 1.4 m.

Preferably, the transverse curved cutouts are symmetrical about the vertical axis of symmetry which runs along the beam axis and constitutes the axis of symmetry of the transverse curved central cutout, while the subsequent transverse curved cutouts are arranged so that their axes of symmetry are spaced from each other by a distance d which is between 0.9 m and 1.5 m, wherein the distance between two adjacent transverse curved cutouts constitutes a rib whose length is 0.2 of the chord length a and the transverse curved cutouts are made in a number corresponding to the maintenance of full transverse curved cutouts, so that at the abutments the length of the rib of the full height section H is not less than 0.5 of the chord length a and not less than the height of the section at the support location.

Preferably, the pin elements are positioned symmetrically between the axes of the cutouts at the full height H.

The advantage of the solution used is easy access to installation zones and no need for additional work during renovation or repair of the installation, due to the fact that the installations are routed in the lower zone of the beam.

The main advantage is the use of a curvilinear cutout instead of a cutout with a rectangular cross-section, for example, due to the structure's performance, especially the lower concentration of tensile stresses.

Another advantage is the retention of similar mechanical properties to a beam without cutouts, despite the provision of installation channels.

Another advantage is the simplicity of the design.

The advantage of using a curved cutout instead of a cutout with a rectangular cross-section is that it allows for better structural performance, especially due to the lower concentration of tensile stresses. BRIEF DESCRIPTION OF THE DRAWING FIGURES

For a proper understanding of the invention, it is illustrated in the examples and in the attached drawings, in which:

Fig. 1 - shows a view of a wooden structural beam;

Fig. 2 - shows the view

A) cross-section of a wooden structural beam at the full cross-section, i.e. without cutouts;

B) cross-section of a wooden structural beam in a place with a curvilinear cut-out with a steel tie in the form of a flat bar;

Fig. 3 - shows a detail view of an abutment in a wooden structural beam;

Fig. 4 - shows a view of a wooden structural beam with dimensions marked.

The wooden structural beam in the attached figures is shown only as an example, while the final shape and dimensions depend on the use of the beam in a specific structure.

METHODS OF CARRYING OUT THE INVENTION

The following examples illustrate the invention without limiting it in any way.

Example 1. WOODEN STRUCTURAL BEAM

Figures 1 and 4 show a wooden structural beam 1 made of homogeneous glued structural timber of class GL24h with the following dimensions:

- length L = 15 m;

- cross-section height H = 1 m;

- cross-section width b = 0.25 m.

The lamellas are glued with resorcinol adhesive. The transverse curved cutouts 5 in the tension zone have the following dimensions:

- Bow chord length h = 0.25 m;

- Bow chord length a = 1 m;

- Length of the abutment a1 = 0.5 m of the wooden structural beam, distances between the cutouts in the arch axes d = 1.2 m.

A flat bar 2 made of S235 structural steel with dimensions of 250 x 25 [mm x mm] is fastened with hot-dip galvanized or galvanized M20 threaded rods of class S235. The first fastening is located at a distance of ci = 0.25 m from the support. Fastening is performed in places where the beam has a full cross-section (B-B), symmetrically in the center between the axes of the curved undercuts, at 1.2 m intervals. The beam is equipped with pin elements 3, which are used to fasten the flat steel bar in the tension zone. These elements are arranged symmetrically between the axes of the undercuts, at places of the full beam height.

The ribs 4 are located between the transverse curved cutouts 5 and ensure appropriate stiffness and force transfer in places where the beam cross-section is full.

The transverse curved cutouts 5 have an elliptical or circular shape and are arranged symmetrically with respect to the vertical axis of the beam, which enables the installation to be guided and reduces the concentration of tensile stresses.

Example 2. WOODEN STRUCTURAL BEAM

Figures 1 and 4 show a wooden structural beam 1, which is made of homogeneous glued structural timber of class GL32c with the following dimensions:

- length L = 15 m;

- cross-section height H = 1 m;

- cross-section width b = 0.25 m.

The slats are glued with resorcinol glue.

The transversely curved cutouts 5 in the tension zone have the following dimensions:

- bowstring length h = 0.3 m;

- arc chord length a = 1 m;

- abutment length a1 = 0.5 m of the wooden structural beam 1, distances between the cutouts in the arch axes d = 1.2 m.

Flat bars 2 are made of S235 structural steel, measuring 250x20 cm, and are fastened with hot-dip galvanized or electroplated M20 threaded rods. The first fastening is located at a distance from the support of c1 = 0.25 m.

The fastening is located in places of the full cross-section (B-B) of the beam and is arranged symmetrically in the middle, between the axes of the curvilinear undercuts, at a distance of c = 1.2 m.

LIST OF NOTATIONS:

1. Wooden structural beam;

2. Flat bar;

3. Pin elements;

4. Rib;

5. Curvilinear cutout;

1a - cross-sectional view of the beam in the place without the cutout;

1b - cross-section view of the beam in the place with the cutout and steel tie;

L - beam length;

H - beam height;

h - notch arrow;

a - length of the cutout chord;

b - beam width;

c - slat height;

dl - distance between the support and the axis of symmetry of the first cut-out; d - distance between the axes of symmetry of the individual cut-outs;

a1 - length of the beam abutment to the first notch;

cl - distance of the first fastening from the support;

g - height of the shorter edge of the flat bar;

n - number of lamellas.

Claims (3)

1. A wooden structural beam constructed of segments in the form of longitudinal lamellas of glued wood, equipped with reinforcing elements in the tension zone in the form of pin elements and flat bars of structural steel, intended for use as a girder element in construction, characterized in that along the wooden structural beam (1) there are at least three transverse curved cutouts (5) arranged symmetrically with respect to the vertical axis of symmetry of the beam and at least two ribs (4) which are located between the transverse curved cutouts (5), wherein the transverse curved cutouts (5) have an elliptical or circular shape with the dimensions: - chord a, which has a length of 0.75 m to 1.25 m and - arrow h, which has dimensions from 1/4 to 1/3 of the total height of the beam (1) H, where the height H of the beam (1) is the number n of lamellas with a single height c and H is in the range from 0.8 m to 1.4 m. 2. Wooden structural beam according to claim 1. 1, characterized in that the transverse curved cutouts (5) are symmetrical in relation to the vertical axis of symmetry which runs along the axis of the wooden structural beam (1) and constitutes the axis of symmetry of the transverse curved cutout (5) central, while the subsequent transverse curved cutouts (5) are arranged in such a way that their axes of symmetry are spaced from each other by a distance d which is between 0.9 m and 1.5 m, wherein the distance between two adjacent transverse curved cutouts (5) constitutes a rib (4) whose length is 0.2 of the chord length a and the transverse curved cutouts (5) are made in a number corresponding to the maintenance of full transverse curved cutouts (5), so that in the place of the abutments of the length of the rib (5) the cross-sections of full height H are not less than 0.5 of the chord length a and not less than the height of the cross-section at the support point. 3. A wooden structural beam according to claim 1-2, characterized in that the pin elements (3) are positioned symmetrically between the axes of the transverse curved cutouts (5) in places of the full height H.