FR2487888A1 - Laminated wood T=section beam - has discontinuous-web reducing material used and allowing fixing of cross purlin - Google Patents

Abstract

The flanges (1) of the beams have at least three plies and the holes in the web (6) are exactly spaced and formed by spacing the web sheets. The faces of the web remain rough because the sheets that form it are not dressed but they can be flushed during the assembly of the elements. The beams allow purlins to be cantilevered at right angles to the gaps, the ceiling can be placed on the purlins followed by a large thickness of insulation, and then the roof is placed to cover all elements.

Description

 The present invention relates to wooden elements, of any shape, intended for producing the structure of all final or temporary constructions. It relates in particular to the production of frameworks, floors and formwork frames. The quality of appearance of the elements combined with the ability to integrate the ceiling and the jibe offer new architectural possibilities. The reduction in raw material recorded (both for wood and for glue), combined with the possibility of integrating large thicknesses of an inexpensive insulation material (glass or rock wool, expanded polystyrene ...) allow economic construction, both for purchase and over time (zero maintenance).

 The structural elements of glued laminated wood, as they are currently manufactured are of rectangular section, and their manufacture as well as their finish (the large faces of the section having to be planed) cause a loss of wood which varies from 30 to 50% compared to the cube of the finished element. In addition, to ensure positioning, all the boards must be butted; machining whose impact is from 8 to 15% on the price of the elements, ex works.

 The manufacture of elements with an I-section has been abandoned due to the difficulties encountered in making the lamellae constituting the core flush, and especially in planing the two faces of the core; especially as it could be of variable height.

 The design of the structural elements proposed by the present invention makes it possible to avoid these drawbacks, and to widen the field of application of the glued laminated timber frame.

 Thus, for equal performance with the traditional glulam, the elements designed according to the invention allow a significant saving of wood, since of the order of 12 to 15%. The members representing a small volume, and being the most requested, they can be made of very good quality wood, obtained by the purgeoge of the defects before joining; composed of a small number of strips, it is easy to flush them, which reduces losses during planing. The core being thinner, this allows the use of very thick strips, especially as they are punctually interrupted; as it is short timber which it is not necessary to butt, it is very easy to have them flush. Hence the use of planks calibrated in width by sawing (bastings or split planks). The friend's facing remains rough, and the application of a fairly dark stain fades the glue joints; moreover, because of the state of the surface, it impregnates the wood better.

The discontinuity of the friend results in recesses (or alveoli) of different shape or by the superposition of the lamellar joints, depending on the destination of
construction, and depending on whether the jibe is placed on the element or placed in the height of the core. Finally, it should be emphasized that due to the small thickness of the core, and the large thickness of the lamellae which constitutes it, the quantity of glue used is greatly reduced.

 The use of elements having an I-shaped section and comprising cells allows a new architectural expression of the glulam, and gives it a particular cachet. It allows the use of glued laminated timber for the realization of numerous constructions from which it was previously excluded, and in particular those whose range is between 10 and 20 meters.

However, one of the original features of the system lies in the possibility of placing the purlins in the alveoli (which allows the implementation of cantilever purlins); hence the following consequences for the whole construction.

- The ceiling can be placed on the purlins (which avoids any scaffolding) and receive a flexible insulating material, at least 15 cm thick, as well as all cables and conduits necessary for the operation of the construction.

- The ceiling can be made of a sufficiently rigid material (such as particle board) which ensures the bracing of the yaw of the roof under the effects of the wind.

- Combined with a cover in dark-colored steel tanks, for example, the ceiling - insulation - cover system allows the recovery of solar heat, knowing that this recovery can be extended to the walls (the hot air being evacuated to the outside the building, when the outside temperature is high). Finally, it should be noted that the elements designed according to the present invention admit a fire stability of at least half an hour, and that the I-shape, as well as the presence of the cells facilitate its handling and lifting.

 Figures 1 and 2 show the design principle of the elements whose members 1 are formed of at least three strips. Breakdown 2 is taken up by posts 3, to which it is connected by pins 4. The joints of the friend's outer strips 5 are placed outside the cell 6.

Given the shape of the cell, the use of posts is essential for the clamping of the assembly of the element on the mold, a separate manufacture of the core elements and of the members being possible.

 Fig. 3 illustrates a curved element which receives the jibe on the upper edge. On the left, the socket has the shape of an oval; on the right, there is no recess, but the arrangement of the joints allows the slats to be flush.

Figs. 4 and 5 represent the principle of integrating a rigid ceiling 7 and a high thickness of insulation 8 based on glass wool. The section of the cells corresponds to that of the purlins 2, which are maintained by the posts 3 (or boxes), and distributed according to the module of the ceiling panels. The cover support battens 9 can be arranged independently of the purlins 2 and rest on intermediate joists
Fig. 6 shows a ceiling panel 7 made of particle board, stiffened lengthwise, by a cleat 11, a joist-crossbowman 10, and an intermediate stiffener 12 (The ceiling can be made from other materials such as steel, aluminum tanks, etc.).

 Figs. 7 and 8 illustrate the arrangements which make it possible to recover the solar heat captured by a cladding and a covering in a dark-colored steel tank 13, for example. For this type of cover, cleats 14 are nailed to the cover support cleats 9. The hot air is collected at the level of the ridge by a sheath delimited by the insulation 8, and is introduced into the heating circuit, or evacuated outside by fans, as required (the running of the fans being controlled by a temperature sensor).

 Figs. 9 and 10 represent two examples of application. In the first case, the beams produced according to the present invention support false rafters 15, which can be distributed as a function of the size of the ceiling panels. In the second case, the beams are placed on molded posts 16, made of solid wood, the assembly of which ensures stability during lifting; final stability can be ensured by ceiling panels which transmit forces to one or two gables, or by embedding the text of one or two posts in the case of low-rise constructions. Multiple combinations can be envisaged, with or without acroterion. Similarly, gantries can be made on poles, the latter being of variable section and made in the same way as the rafters, or metal.

 At present, most industrial and commercial constructions use structures with a span of 10 to 20 m, dimensions for which conventional glue-laminate is not competitive; moreover, the currently proposed designs lead to an obstruction of the volumes (stick of the arches, molded posts of the porticos). In addition, taking into account the rise in energy, the owners demand constructions whose wall and torture are perfectly isolated. However, the elements produced according to the present invention make it possible to economically resolve these problems; moreover, they do not require any maintenance, facilitate 'integration of the finishing work as well as the transformations, offer a good fire stability, ensure a reliability of the thermal insulation (absence of thermal bridges), and contribute to the quality aesthetic as well as personalization of the works.

Claims (4)

 1. structural elements in glue-laminated wood, characterized in that their section is in I, and that the friend is discontinuous; discontinuity materialized by point cells (6), or by the non-abutment of the slats. The faces of the 1'8me remain rough, because the lamellae constituting it are interrupted and can thus easily be flush when the elements are tightened.  2. Structural elements according to claim 1, characterized in that they allow the implementation of cantilever purlins (2) in line with the cells (6) of ob the possibility of placing the ceiling (7) on the purlins (2), then a high thickness of insulation (8). In addition, the center distance of the ceiling supports can be different from that of the roof supports.  3. Structural elements according to claim 2, characterized in that they can be placed on posts (16) of small section. For low-rise constructions, the post or posts are recessed at the head for the others, the ceiling panels (7) provide bracing under the effects of the wind, by transporting forces on one or two gables.  4. Structural elements according to claim 2, characterized in that they allow the recovery of solar heat, by providing, for example, a cover in dark-colored steel tanks (13).