The invention concerns a panel element made of wood, and/or a beam made of wood, in accordance with the features in the preamble of claims 1 and 15.
One of the many uses of wood as a material is that for the construction of buildings as a building material, for example in traditional forms of building such as the log cabin style. As conditioned by an increasing demand for wood as a building material, however, the latter is also gaining increasing importance in prefabricated house construction, and in the construction of new buildings. Here larger prefabricated wall elements are in particular coming into use to some extent. In addition to use as wall elements, such panel-form elements made of wood can also be deployed in the manufacture of floors and ceilings. In addition to wall elements made of wood, however ties made of laminated wood, also designated as gluelams, are also of importance; these can be used as uprights or as load-bearing components for roof trusses.
By virtue of an increasing level of health awareness in large parts of the population, and a thus hoped for improvement in living standards, the question of the elimination of additives, such as, for example, glue for joining the wooden parts is attracting more and more interest in the manufacture of such panel elements made of wood.
From the prior art wall elements of buildings, such as are described in the documents EP 1 734 200 B1 and EP 2 060 694 B1, are already of known art. The document EP 1 734 200 B1 describes a wall element of a building in the form of a composite panel of wood plies with at least two plies of timbers, in each case arranged adjacently to one another in layers. The two plies are connected with one another by means of grooves located opposite one another and therein-inserted dovetail battens. The document BE 503 355, on the other hand, describes a component made of a plurality of timbers oriented in parallel connected so as to form an element. For purpose of connecting the timbers to one another projections and depressions are formed along their lengthwise extent in lengthwise sides facing each other. The cross-section of the projections and depressions is shaped in the manner of a dovetail joint, and the timbers, or wooden parts, are accordingly joined together in a form-fit manner.
The object of the invention is to specify a panel element made of wood, and/or a beam made of wood, which can be used as a structural part in the construction of buildings.
The object of the invention is achieved by means of a panel element made of wood, consisting of at least two layers of boards, arranged in each case lying adjacently to one another in a parallel manner, wherein the boards of a first layer are oriented parallel to boards of a second layer, and wherein a board of the first layer and a board of the second layer are connected with one another by means of dovetail joints, and the dovetail joints are formed by means of a sequence of dovetail-shaped recesses and projections following one another in the direction of a lengthwise extent of the boards, and are shaped in the boards. Here the recesses and projections extend in the direction of a width of the boards, wherein a board of the first layer and a board of the second layer are arranged to be offset relative to each other in the direction of the width and to overlap each other, and the recesses of the dovetail joints have a wedge shape so as to taper from a board edge to a board centre. This has the advantage that in the manufacture of the panel element the boards can be joined together so as to lie close to one another on their contact surfaces. As a consequence a high thermal insulation effect is also achieved in the panel element manufactured in this manner. Moreover, the panel element designed in this manner also has a high internal stiffness and dimensional stability.
By providing the recesses of the dovetail joints on both sides with an inclined position, with a half wedge angle with a value of between 0.5° and 10°, preferably of between 3° and 10°, a simplification of the assembly of the boards to form the panel element is achieved, at the same time with high internal strength and stability.
The design of the panel element, whereby a board of the first layer and a board of the second layer overlap each other over an overlapping width having a value that is equal to or greater than 10% of the board width, has the advantage of an increased dimensional stability for the structure of the panel element formed by the boards.
In accordance with a further development of the panel element provision is made for the dimensions of the projections to be selected in proportion to the dimensions of the recesses such that boards of one respective layer lie against one another so as to be gap-free. This has the advantage of an increased thermal insulation effect of the panel element, in that the effective thickness of the panel element is correspondingly greater.
By ensuring that in the panel element the value of the overlapping width corresponds to approximately one half of the width of the boards, and a tongue-and-groove joint is designed between boards lying adjacent to one another and within one layer, both the insulating, that is to say, heat blocking, effect of the panel element is improved, and also a reinforcement of the joint between the boards is achieved, in that an additional force-fit connection effect is achieved by means of the tongue-and-groove joint.
A further development of the panel element, whereby the projections and the recesses of the boards are symmetrically disposed with respect to a centre plane at right angles to the width of the boards, has the advantage that by this means the manufacture of a system of uniformly shaped boards is enabled. Uniformly shaped boards of the same basic shape can thus be assembled together in a modular manner to form panel elements.
Provision can furthermore be made for the dimensions of the recesses to be calculated such that a clear width at the edge of the board equals a width of the projection in the region of the centre plane. By this means it is advantageously achieved that the boards can be arranged so as to lie close to one another, thus filling the space.
In accordance with a variant of embodiment of the panel element, provision can also be made for a beam to be arranged in a first end region with respect to a lengthwise axis of the boards, and for the said beam to be oriented at right angles with respect to the boards. By this means an increase in the rigidity of the shape of the panel element is advantageously achieved.
Furthermore, by arranging the beam to be located between the first layer and a third layer made of boards, that is to say, such that the beam has a thickness, the value of which is equal to a value of the thickness of the boards, a standardised configuration of the end regions of the boards is enabled.
[In accordance with a further development of the panel element, provision can also be made for a beam to be accommodated in a region distant from the two end regions, which beam is oriented so as to be parallel with the beam located in the first end region, and is disposed between the layers. Thereby, and by means of the measure whereby the boards and the beam are fixed to one another by bolts that pass through the boards and the beam, an even greater rigidity of the shape of the panel element is achieved.
By forming depressions in the projections of the boards for the purpose of forming cavities in the panel element, the formation of air-filled cavities in the panel element is enabled; these advantageously effect an increase in the thermal insulation properties of the panel elements.
[In accordance with a further development provision is moreover made for grooves to be formed in the projections. This allows a simpler manufacture of the depressions for the purpose of forming cavities.
In accordance with a variant of embodiment of the panel element provision is made for additional wooden cladding to be arranged on one of the layers made of boards, wherein the wooden cladding comprises a layer of boards lying adjacently to one another in a parallel manner. This has the advantage of a greater variety in the selection of configurational options for the surfaces of the panel elements.
For a better understanding of the invention the latter is described in more detail with the aid of the following figures.
Here, in each case in a highly schematic simplified representation:
By way of introduction it should be noted that in the various forms of embodiment described the same parts are provided with the same reference symbols, and/or the same component designations, wherein the disclosures contained in the whole description analogously can be transferred to the same parts with the same reference symbols, and/or the same component designations. Also the location details selected in the description, such as e.g. above, below, at the side, etc are referred to the immediately described and represented figure, and in the event of an alteration of location are to be transferred analogously to the new location. Furthermore individual features or combinations of features from the various examples of embodiment shown and described can also represent in their own right independent inventive solutions, or solutions in accordance with the invention.
All details regarding ranges of values in the representational description are to be understood to mean that these include any and all sub-ranges of the latter, e.g. the statement 1 to 10 is to be understood to include all sub-ranges, starting from the lower limit 1 and the upper limit 10, i.e. all sub-ranges begin with a lower limit of 1 or more, and end with an upper limit of 10 or less, e.g. 1 to 1.7, or 3.2 to 8.1, or 5.5 to 10.
The connection of the individual boards 2 to form an overall rigid shape of panel element 1 is achieved by providing a form-fit joint between boards 2, 6, 8 in the regions of the overlapping width 9. This joint is preferably designed in the manner of a dovetail joint. The functionality of this joint can be explained on the basis of the region represented on the right below in
In the board 8 of the second (upper) layer 4, on the other hand, provision is made for its side facing the first (lower) layer 3 to have a complementary configuration to the recesses 11 and projections 12 of the board 6 of the lower layer 3. In the state in which they are joined together, projections 12 of the board 6 therefore engage in recesses 11 of the board 8, and vice versa.
The assembly of the boards 2, 6, 8 to form the panel element 1 can thus take place such that projections 12 and recesses 11 of the first board 6 and the second board 8 are oriented such that they are aligned with one another, and the two boards 6, 8 are moved one upon another in the direction of the width 10, and finally these are joined with one another by the insertion of the recesses 11 and the projections 12 into one another.
In accordance with this example of embodiment provision is also made for the cross-section of the recess 11 not to be constant over the width 10; instead it is variable. In actual fact the recess 11 is formed in the shape of a wedge so as to taper from a board edge 13 to a board centre 14. Thus on both sides the recesses 11 have an inclined position with a half wedge angle 15. The projections 12 and the recesses 11 of the boards 2 are moreover symmetrical with respect to a centre plane 17 at right angles to the width 10 and containing the board centre 14. The value of the half wedge angle 15 is preferably selected from a range between 1.5° and 10°, preferably between 3° and 10°.
In the example of embodiment of the panel element 1 as in
The projections 12 and the recesses 11 are preferably formed symmetrically with respect to the centre plane 17, with a half wedge angle 15. At the same time the dimensions of the recess 11 are calculated such that a clear width 23 at the edge 13 of the board 2 equals a width 24 of the projection 12 in the region of the centre plane 17. Thus a region 25 of the projection 12 and a region 26 of the recess 11 are formed; these are indicated in
The design of the grooves 20 and 21 on the narrow sides of the boards 2 is configured such that projections located between the grooves 20 can be inserted as tongues into the grooves 21 of another board 2 (
The inventive boards can be manufactured on a basis of conventional boards with a rectangular outer boundary. To this end the recesses 11 and the grooves 20, 21 are formed using appropriate tools in what is initially an unmachined board with a width 10 and a thickness 27. This work can, for example, be executed using appropriate sawing and/or milling tools. Here the recesses 11 are calculated such that a value of a depth 28 lies in a range from 10% to 30% of the thickness 27 of the boards 2.
[As a result of the additional provision of the beam 41 in the panel element 1, an even greater rigidity is achieved for the shape of the panel element 1. Deformations, such as can occur in the case of boards made of sawn wood, as is well-known, as a consequence of an alternating moisture content as a result of drying out, or the absorption of moisture in environments with a high air humidity, can at least in part be intercepted by the mechanical strength of the beam 41, and thus prevented.
As an alternative to the grooves 48 in the projections 12 that are oriented parallel to the lengthwise axis 5 of the boards 2, however, grooves that are otherwise oriented, or depressions that are shaped in quite another manner, can also be provided for the purpose of forming closed cavities in the panel element 1. At the same time, however, it is also possible for further depressions to be provided in the material of the board 2 in the region of the recesses 11 for the purpose of forming intermediate cavities.
In an alternative variant of embodiment, however, the connecting element 57 could also be joined in the form of a tongue-and-groove joint with the boards 2 on the one hand, and the boards 56 of the wooden cladding 55 on the other. That is to say, the connecting element 57 is formed as a so-called tongue, and the wooden cladding 55 is then attached by means of a force-fit joint onto the boards 2.
With the aid of
In an alternative form of embodiment, however, it would also be possible to provide an inclined position of the sides of the projections 85 and the recesses 84 on only one side. In accordance with further variants of embodiment a beam 80 composed of layers can also be composed of only two boards 81, 82; however, it can also be formed by more than three boards 81, 82, 83.
The examples of embodiment show possible variants of embodiment of the panel element 1, wherein at this point it is noted that the invention is not limited to these particularly illustrated embodiments but also diverse combinations of the individual variants of embodiment amongst themselves are possible and this possibility of variation on the basis of the technical information of the present invention lies within the capability of the skilled person active in this technical field. The scope of protection also comprises all conceivable variants which are possible by combining individual details of the variants described and illustrated.
For the record, it should finally be noted that for a better understanding of the construction of the panel member 1, the latter, or more particularly, its constituent parts, are on some occasions not drawn to scale, and/or are on some occasions enlarged and/or reduced in size.
The independent inventive solutions of the underlying task can be taken from the description.
Above all, the individual embodiments shown in
Number | Date | Country | Kind |
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13174730.5 | Jul 2013 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/063288 | 6/24/2014 | WO | 00 |