LV15154B - Method for production of composite structural members using standard wooden elements having plane and parallel lateral faces - Google Patents

Description

Description of the Invention

The present invention relates to a method of fabricating structural composite elements of arches by means of standard flat parallel wood elements which, according to the method of the invention, can be assembled into parts by means of multi-layer arches or circular structures in which the elemental layers are arranged vertically. The invention can be used to make wooden arches, including greenhouses, hangars, roof structures, bridges or molds for construction. The invention may also be used for other purposes, such as in the manufacture of wooden toys.

The invention allows to minimize the number of assortments (standard elements) required for arch construction, due to the relatively small size of the inventive technology, compact packaging, thus significantly reducing the costs of transportation, production, distribution and logistics processes. .

Analysis of known known angular joints

There are many common joints in wood and furniture joinery, including cross and end joints of boards and / or joists, longitudinal joints of joints (including butt joints, butt joints, longitudinal flush joints) as well as angled joints (one straight ledge) , two or more straight ledges, penetrating liners or recessed ledges), etc. All of the above-mentioned angular joints of wooden parts are of two-piece construction, each of which is an integral piece with a sufficiently complex, technologically difficult milling profile, and are mainly intended for joining the corners of the parts at right angles rather than circumferentially.

Patent application US2478421 A is known in which the claimed invention can only effectively influence the vertical load distribution up to the arch plane of the joints parallel to the longitudinal plane of the parts, and thus the loads are effectively distributed only up to the joint.

Technical Purpose and Nature of the Invention

The technical object of the present invention is to provide a method of fabricating composite arch components using simple, flat, parallel wood elements to form a multilayer arch structure in which the layers are positioned vertically relative to the longitudinal axis of the arch. If the invention is compared with the aforementioned patent application US2478421 A, the element-joining solution proposed in the invention can withstand higher loads, because the principle of element-part joining enables to create a three or multilayer glued wooden arch, where the layers are arranged vertically with respect to for the axles, the load distribution shall be uniform throughout the arched cross-section.

The proposed method of fabricating structural structural composite elements of an arch is characterized in that (see claim 1), by using standard flat parallel elements of wood, hereinafter referred to as elements, to be glued together and / or secured in any other manner according to the principle of the invention. In an acceptable manner, composite components consisting of at least three of these elements as forming layers, hereinafter referred to simply as parts, may form multilayer high strength arches with layers oriented perpendicular to the longitudinal axis of the arch and having the number of layers equal to the number of elements in cross section. Embodiments of the invention are defined in claims 2 to 10.

According to the invention, the arch as a whole is formed either of one type of laterally identical elements (A) or two types of elements (B and C) having different lengths and angles. Depending on the number of elements in a single part and how they are connected in parallel, the characteristics of the parts (length, thickness, number of layers, load-bearing capacity, etc.) differ which are not the object of the present invention.

Brief Description of the Drawings Accompanying the Invention

Some examples of an embodiment of an arch detail arrangement used to implement the proposed method according to any one of claims 1 to 10 and their use are shown in the attached eight drawings. In the specification and drawings, the plus sign (+) denotes the parallel arrangement of elements in a node, the minus sign (-) denotes the arrangement of nodes in a string, and the sign (') denotes a mirror symmetric element.

Fig. 1 in various views, the arc part X shown in 1.1 and 1.2 is made up of the same elements (A), respectively, X = A + A '+ A'.

Fig. 2 in various views, the arc part Y shown in 2.1 and 2.2 is composed of elements (B and C), respectively, Y = В + C + C.

Fig. 3 in various views, the arch part Z shown in 3.1 and 3.2 is also made up of elements (B and C), respectively, Z = С + B + B.

Fig. 4 is a side view of three arch variants 4.1, 4.2, and 4.3, respectively, made of details: Z and Y; only from X; X, Y and Z shown in FIG. and Figs.

Fig. 5 the side view shows one of the possible angles of the elements (А, В and C).

Fig. 6 the three-dimensional representation depicts a component X for which mutually compatible milling patterns are formed, also denoted by indexes 1 and 2.

Figures 7 and 8 some embodiments of the invention for the construction of load-bearing arched structures are shown.

DETAILED DESCRIPTION OF THE INVENTION

The arch parts used to carry out the proposed process according to any one of claims 1 to 10 consist of three or more elements, wherein different types of elements are denoted by different capital letters (А, В and C). These parts require three types of elements, from which they can be glued together to form the parts shown in the drawings and to form arched structures. If milled elements are used to create parts, such (framed) elements must be present throughout the arch element layer. For milled elements, the arch is formed so that the surface milling elements of the element milling are parallel to one another at one end of the part, so that the condition is necessary to allow the parts to be connected to each other along their length. The shape of the millings should preferably be in the form of a dovetail connection similar to that of the hook or of the hook type milling shown in Fig. 6. Parts can also be made from non-milled elements, but in the process of joining such parts, it is necessary to use glue to form an arch.

In the drawings appended to the description of the invention, the arch parts consist of elements (А, В and C) of which (A) are parallelogram-shaped (different end angles) elements, and (B and C) are trapezoidal elements arranged symmetrically in a vertical plane. against the median plane. Conditionally, all types of elements can also be subdivided into subgroups based on material, length, thickness and angle of inclination, number of element layers, etc. parameters. The ends of the elements (A) have different inclination angles, the difference of which depends directly on the size of the arch segment occupied by one element. The sum of the angles of the ends of the element (A) is calculated by the following formula: the number of degrees of arc of the arc is to be divided by the number of units of that element in the circle. In this way, the sum of the angles at the ends of the element (A) can be found. Similar angular difference and interconnection also exists for trapezoidal elements (B or C), where the trapezoidal elements in the element have the same but opposite angles, but according to the above relation angles differ between different (B and C) trapezoidal elements of this type for elements, the difference in angles is calculated in the same way as for end elements of type (A): the number of degrees of arc is to be divided by the number of elements of a single layer in the arc and thus the sum of angles at the ends of elements (B or C). With respect to the median plane of the arch-forming composite members, the outer members are uniformly oriented relative to each other, and the inclination angles of the composite members are symmetrical within one part. The orientation of the elements (A or A '), analogs (B or C), located in the middle layer of the component, is such that their angularly formed ends are mirror-symmetrical with respect to the angular ends of both outer layers. The planar parallel arrangement of the elements in the component layers should preferably have a greater or lesser offset relative to the longitudinal axis such that the elements are not disposed in lateral view but are mutually offset provided that the parallel edges (top and bottom) of each element are must be perpendicular to the radial axis of the arch.

For component planes interconnecting longitudinally with the perpendicular planes of adjacent parts, FIG. indices 1 and 2 are assigned. Plates to which indices 1 and 2 are assigned are mutually compatible feats. The non-marking part joining planes are non-milled, compatible with each other and glued together. It is desirable to interconnect the elements in the component with offset so that the component joints in the parallel layers are not in the same plane, provided that the upper and lower planes of the elements must be perpendicular to the arc radius.

Using Fig. It is possible to create an arch structure from one of the same type of similar parts shown in Fig. 4.2. and consist of equal elements (A).

Using the combination of elements shown in Figures 2 and 3 in parts Y and Z, it is possible to create the arch structure Z-Y-Z-Y-Z-Y shown in Fig. 4l.

Using Fig. 1, Fig. 2. and Fig. 3, it is possible to create the arch structure XYZXX in parts X, Y and Z of Fig. 4.3, provided that the part X at the ends of the arch or the sequence of several parts at the ends of the arch XX must be different from Z and Y parts, or the same X part, which extends the sequence of X parts (subject to these conditions, the parts can also be aligned in a different combination to form other different structures).

Fig. 6 the middle parts of the part shown are milled, denoted by indexes 1 and 2. The forms of milling 1 and 2 are mutually compatible, and from these parts, thanks to the mutually compatible milling of said elements, it is possible to form an arch without the use of glue. Unlike Fig. 6 it is also possible to make millings of the illustrated variant which perform the function of joints on the surfaces of other elements provided that the elements must be aligned in the part so that the planes of the milled surfaces are parallel to one end of the part.

The experimental test of an arch made of spruce boards according to the invention yielded the following results in practice:

- the three-layered arch (6x8 cm; 7.85 meters; diameter 5 m), in which the joints in two of the three layers were approximately in the same plane, broke at a load of 640 kg (the load was intentionally applied unevenly and the arch was rocked);

- the three-layer arch (6x8 cm; 7.85 meters; diameter 5 m), in which the parallel planes of the joint planes were not in one plane, was broken at a load of 1220 kg (as in the first version, the arch was intensively rocked);

- if the load is applied evenly or only in the middle of the arch, the arch can withstand a significantly higher load (in the first case 700 kg, in the second case 1400 kg) but taking into account that the arch is expensive and is a realistic application, for example, for the production of a lattice frame for a greenhouse, experiments with steady loads have not been developed.

Used information sources:

1. Regulations of the Cabinet of Ministers No. 140 Regulations on Latvian Construction Standard LBN 206-99 “Design Standards for Wooden Structures” http://likumi.lv/doc.php?id=23616

2. RIGA TECHNICAL UNIVERSITY Doctoral study program “Construction” summary of the thesis “NON-TRADITIONAL ELEMENTS OF WOOD COMPOSITE STRUCTURES AND METHODS OF CALCULATION”> file: /// D: / Users / Lauris / DownIoads / suml 564.

3. THREE-CYCLING SYSTEMS http: //www.bf.rtu.lv/documents/edu/bm/bm2 5 .pdf

4. US Patent Application US2478421 A (Arches or top chord construction).

Claims (10)

Claims 1. A method of fabricating structural composite arch elements using standard planar parallel wood structural elements (A, В and C), wherein the elements (A) are parallelogram shaped elements with different angles at their ends and (B and C) are trapezoidal elements of the same type, but at opposite angles at the ends of the elements, or their counterparts, rotated accordingly about their longitudinal axis, and structured symmetrically with respect to the median plane of the element element to be formed, and glued to each other to form at least a three-layer beam type X, Y, Z, which arches are fixed to each other during the assembly process. A method according to claim 1, wherein the thickness of the forming elements in each of the component layers is constant, and the forming elements X, Y, Z (А, В and (C) the thicknesses may be different provided that they are symmetrical in relation to the median plane of the component packet (part). The method according to claim 1 or 2, wherein the elements in the part package forming process are arranged such that their lower and upper edges are substantially perpendicular to the radial axis of the arch and at least in one of the layers the elements are opposite to the angle of the adjacent layer elements. that is, if one element is placed, for example, element (A), then an element (A '), which is the same as element (A), but inverted along its longitudinal axis, is placed in the adjacent layer so that , a single layer interconnected element (A) with (A) or (A ') with (A'), whereby: - the angles of inclination of the ends of elements A or A 'are different, and this difference is a function of the length of the arch segment occupied by one element, and the sum of the angles of the ends of element (A or A') is calculated by the following formula: the number of single-layer elements in the arc; analogous to the case when the part is made of elements (A and A '), the sum of the angles is calculated even if the part is made of trapezoidal elements (B or C), whereby the same type of trapezoidal elements have the same angles, the difference in angles between the trapezoidal elements is between the different elements (B and C). - the elements are arranged in the part-forming process so that the angles of at least one layer of elements in the cross-section of the beams are preferably opposite to those of the adjacent layer elements, ie if at least one of the layers is placed in one part of the layer element C must be placed A method according to claim 1, provided that the requirements defined in claims 2 and 3 are met, wherein the arch part X = A + A '+ A' (Fig. 1) is formed from the same elements (A). and by using a combination of said elements in the part, the arch structure ...- XXX -... is formed from one type of identical parts. The method of claim 1, provided that the requirements defined in claims 2 and 3 are met, wherein the arch member Y = B + C + C (Fig. 2) or the member Z = C + B + B (Fig. 3) are made of symmetrical trapezoidal elements (B and C) and by using said combination of elements in parts Y and Z, an arch structure is created. The method according to any one of the preceding claims, wherein the planar parallel arrangement of the elements in the component layers is preferably characterized by mutual offset relative to the longitudinal axis, provided that the parallel sides (top and bottom) of each element are perpendicular to the radial axis of the arch; thus, using Fig. 1, Fig. 2. and Fig. 3, it is possible to create an arch structure in the parts X, Y and Z of Fig. 4.3, or any other arch structure different from the above, provided that the parts at the ends of X or in the sequence of several parts X. .XX ... there are disjoint parts (Z υη Y) or the same part X extending the sequence of these parts. The method according to any one of the preceding claims and the description of the invention, wherein said component packet is formed of more than three elements (А, В and C) and said elements are arranged in the packet as follows: if element (B) is placed in one layer, at least one of the other layers preferably has an element (C) and, by placing parts on top of each other, different elements are placed at the ends of the element to create an arched load for a wooden residential building, industrial building (hangar, greenhouse, etc.) load-bearing roof structures, as well as structures to support molds for the construction of monolithic reinforced concrete buildings. A method according to any one of the preceding claims, wherein mutually compatible millings are formed in the planes of said elements which join with the compatible element of the other part, which ensure a non-adhesive connection between the parts, the condition being met when using the milled elements. that the milled elements are arranged such that the milled planes are parallel to each other at the joints of the parts. A method according to any one of claims 1 to 7, wherein the non-milling planes of the interconnections of said elements are bonded using an adhesive. The method according to any one of the preceding claims, wherein the quality, assortment, strength properties and processing characteristics of the wood raw materials used in the method, including the angular peel angles, the number of layers and the thickness of the elements in the layers to form arched wood constructions .