• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to new lamellas of natural wood with straight-line converging longitudinal side edges delimited trapezoidal, mutually parallel broad or principal planes, which are characterized in that their two mutually parallel principal planes (11, 12, 11 ', 12', 11 '', 12 ''), bounded by the converging longitudinal side flanks (13, 14, 13 ', 14' ', 13' ', 14), the shape of geometrically similar to each other, a) isosceles, or b) have unequal limb trapezoids. It further relates to the said lamellae (1, 1 ', 1' ') formed boards, beams formed with these boards and further single-layer and multi-layer plates with concomitant use of the slats 1, 1', 1 ''.
    公开号:AT516697A1
    申请号:T50125/2015
    申请日:2015-02-18
    公开日:2016-07-15
    发明作者:
    申请人:Johann Offner Beteiligungs-Gesellschaft M B H;
    IPC主号:
    专利说明:

    Slats of natural wood, boards, beams and plates made of them
    The present invention relates generally to conical lamellae, which are obtained adapted to the natural growth course of pre-sorted logs in chipper circular saw lines with profiling in the cutting of side goods. A conical lamella is characterized by two mutually parallel broad surfaces, which are isosceles trapezoidal, two perpendicular to the broad faces end faces that are rectangular and two normal to the wide surfaces narrow surfaces, which are also rectangular and elongated an acute angle between slat center line and narrow surface form, out.
    For the production of conical lamellae from side products, round wood, as presorted and debarked in the usual processes of the wood industry, is used as the starting product. Each tree trunk has a natural rejuvenation in the direction of growth, which in the following is called deforestation.
    The advantage of producing conical lamellae from the side product lies in the better round timber yield by adapting the lamellar contour to the woodiness of the roundwood.
    By way of example only, consider a parallel-prism blade of dimensions 35x90x4000mm and a conical blade of the same dimension, where the width of the narrow face is 90mm and the width of the larger face is assumed to be 8mm by 1m in length. The increase in the proportion of lumber in this dimension is 15%, decreases linearly with increasing lamella width and is still 7% with a dimension of 35x210x4000mm3 with even deforestation.
    The debarked tree trunks are transported, for example in a Spaner- circular saw line in the longitudinal direction, while the curvature, orientation and size of the end faces is evaluated by 3D measurement in the first station of the entire tree trunk. Furthermore, the tree trunk is pre-positioned by means of rollers so that the predetermined cutting profile of the main product over the entire longitudinal axis is ensured without intersecting the outermost cutting lines in the x and z direction with the naturally grown outer edges of the tree trunk.
    Furthermore, the circle-like contour of the two end faces of the tree trunk is flattened left and right with chippers.
    The two resulting surfaces are parallel to each other and already form the broad surfaces of two conical slats. Furthermore, these surfaces are optically measured to perform the conical trimming in the next step by profiling so that the trimming is within the natural forest edges, which are thus milled away, creating a lamella, which has no forest edges.
    The conicity of the trimming depends on the bulkiness of the pre-sorted round timber. In trimming the tree trunk moves in the longitudinal direction normal to the axis of two Besäumfräser, the cutter start depending on the orientation of the tree trunk, the first incoming end with a smaller diameter from the inside out, that is, an upper cutter moves in z + (plus) direction and bottom cutter moves in the z (minus) direction, with the first incoming larger diameter diameter reversed, with the movement of the cutter being proportionally adjusted to the longitudinal movement of the log.
    The trimming creates the narrow surfaces, normal to the wide surfaces standing. In addition, during trimming, a part of the separating cut between lamellae and trunk is carried out. Finally, the separation cut is carried out by means of two circular saws, which runs parallel to the first wide area at a distance of the lamella thickness. The thickness of the slats depends on the given cutting program. This Besäumvorgang can be performed with a profiling up to six times. The conical lamellae are finished by separating them from the tree trunk in all dimensions, in the undried state, and are finally sorted.
    The remaining part of the trunk is rotated by 90 ° in the y-axis and aligned. Thereafter, the cutting and Besäumvorgang repeated until the cross section of the tree trunk forms a rectangle.
    The remaining tree trunk is divided for the incision of the main commodity.
    All conical slats accumulating in this procedure are sorted and arranged alternately with a narrow end face, a broad end face, a narrower face, a face, etc., stacked in a package. Be between the individual layers
    Inserts interposed to allow air circulation between the board layers. During drying, the conical slats are dried to a moisture content of 8 to 14%. For the production of single-layer slabs of conical slats with load-bearing gluing, the slats are separated and sorted again after drying. The actual moisture content and the visual quality of each slat are determined and faulty slats are possibly eliminated. Subsequently, the arrangement of the lamellae is again adjusted so that successive lamellae are alternately with narrower to broader end side together.
    After orientation, the slats are planed on both narrow sides. They must first be aligned along their midline in the wide area. The narrow surfaces are then machined with planing heads, which move in the direction of the slats in x + (plus) or x (minus) direction, proportionally to the longitudinal velocity as in trimming. Planing removes unevenness caused by shrinkage during drying.
    After planing, there is a glue application, which always only affects one slab per slat. The glue application can, for example, be carried out so that the lamellae are guided between two stop surfaces and, depending on the orientation of the lamella, is aligned either with the surface on the left or on the right.
    The lamella continues to run aligned and after the end of the stop surfaces of the glue application is arranged, which rolls on the narrow surfaces of glue or splashes.
    In a press unit, the slats are brought together so that each glued and unprimed narrow surface of the next slat lie together. The press unit can be, for example, an endless press carpet whose pressure remains constant in the x-direction of the slats. During the pressing process, a constant pressure is applied in the x- and z-direction of the lamellae, in the y-direction of the lamellae, these are guided on both sides to prevent a mutual sliding of the narrow surfaces. The duration of the pressing process depends on the curing time of the glue.
    After gluing, protruding ends, ie mostly the end faces of the conical lamellae, are capped off, so that ultimately a rectangular plate format is created. The length of the plates is variable and they are cut off from the endless format as needed. Finally, the monolayer plates thus obtained are combined in a stacking to a package.
    As far as the previously known conical slats and their production are concerned, reference may be made to EP 2596924 A1, for example.
    The invention relates now, as previously described lamellae made of natural wood with limited by straight converging longitudinal side edges, trapezoidal, mutually parallel broad or main planes, which, however, characterized in that the two mutually parallel main planes of the converging Limited longitudinal side edges, the shape of each other geometrically similar, a) isosceles, or b) unequal limb trapezoids, the lamellae either a) as lamellae with mutually symmetrical, in idente, acute angles each inclined to the said main planes, oblique longitudinal Be present side edges and a total of longitudinally-continuous, in cross-section the shape of geometrically similar, isosceles trapezoids, or b) as slats, each with an inclined at an acute angle to the main planes, sloping side edge and at right angles to said main planes arranged s longitudinal longitudinal side flank present and overall longitudinally in cross-section the shape of geometrically similar, unequal leg trapezoids ("half-trapezoids") have.
    To increase the proportion of sawn timber - as in the case of the conical lamella - the wide surfaces are given an isosceles trapezoidal profile, in addition, however, the cross-sectional profile of the lamella is also equipped with an (un) isosceles trapezoidal contour.
    As an example of calculation, parallel-prismed and trapezoidal conical-prismatic lamellae with a nominal dimension of 35x90x4000mm are compared with an assumed woodiness of 8mm by 1m, whereas in the case of the trapezoidal lamella the length of the shortest end edge is 90mm. The result in this dimension leads to an increase in the proportion of sawn timber by 36%, and with a dimension of 35x210x4000mm to a still 19.5%.
    The production of the trapezoidal lamellae according to the invention runs as in the usual conical lamellae when machining the core facing away from the same pages.
    After cutting the first two wide surfaces, however, the side fabric is not trimmed, but separated from the tree trunk and released from the line. All unedged lamellas are stacked and dried.
    After drying, these unedged slats are processed in a separate production line. The lamella stacks are given to a task, the lamellae separated and handed over to a longitudinal conveyor unit. Furthermore, the unedged lamellas undergo a 3D measurement, whereby the contour of the broad and narrow surfaces is calculated, so that the roundwood is optimally utilized, and no forest edges remain on the finished edged lamellae. The trapeze angles of the broad and the face can vary, but both contours must form an isosceles trapeze. The angles of the trapezoidal end faces are in particular in the range of 30-60 °, preferably about 45 °.
    After the measurement, the unedged lamellas are aligned with the right-hand side and the wide-area lapses that are larger than the surface area and along the center line of the calculated contour.
    The trimming of the narrow surfaces is done with planing heads, which are rotatable about the y-axis, to produce different Trapezwinkel in the end faces. In order to obtain the conical slope of the broad surface, the planing heads are again displaceable in the x-axis, wherein the feed rate is adapted proportionally to the longitudinal velocity of the slats. By changing the feed in the x direction, the conicity changes in the wide area. Therefore, in addition to the contours, the feed required for the trimming cycle is specified during the 3D measurement. Upon completion of the trimming process, a trapezoidal lamella is finished.
    Preferred in the context of the invention, as described above trapezoidal lamellae according to variant b), in which, preferably longitudinally, longitudinal division of a whole lamella according to the above variant a), perpendicular to the two main planes and their two end planes, the lamella in the form of two according to the above-mentioned variant b) formed lamellae are present.
    Furthermore, it is favorable in particular with regard to each further processing steps when the oblique longitudinal side edge (s) of the lamellae are each inclined at an angle of 25 to 70 °, in particular 30 to 60 °, to the main planes of the respective lamella.
    Another object of the invention is a standing with the novel slats in direct relation use of new trapezoidal fins for - in the end usual boards:
    Accordingly, a board which is available with two lamellae according to the above variant b) or according to the above embodiments, also a further essential object of the invention, wherein one of these two lamellas - after 180 ° rotation about a direction parallel to the two main planes extending axis of rotation - materially connected to each other via their main inclined planes inclined at an angle, oblique longitudinal side edges, in particular glued, and the board thus formed thus longitudinally-consistent constant rectangular cross-section.
    However, these new, interconnected via their oblique flank surfaces lamellae are characterized on the one hand as a result of a kind "sandwich effect" and on the other hand due to the tree longitudinal fiber compliant trimming by higher strength, but a common use of previously known, common boards, e.g. in multi-lamellae and -Bretterkonstrukten, nothing stands in the way.
    The production of single boards made of trapezoid conical slats can be linked directly to their trimming. Hiebei the slats are divided, for example, in the center line of the wide surfaces with a separating cut in two half-trapezoidal cone slats longitudinally. One of them is rotated by 180 ° about the z-axis, on the narrow surface of this half-lamella glue is applied. The second half-blade is rotated 180 ° about the y-axis and merged with the other half-blade in a press unit, so that both narrow surfaces lie together. The gluing is carried out. During the pressing process, a pressing pressure in the wide surfaces and the separating surfaces of the slats is initiated, against sliding of the two halves against each other, the end faces are supported.
    In this case, the production of parallel single boards is independent of the conicity of the broad and end faces of the slats, as always a parallel flanks extending perpendicular to the broad or main surfaces, having single board is glued from two halves of the same slat.
    Of course, with the new boards, endless boards can be created which are formed with individual boards, preferably closed together by means of flat or vertical keyed zinc joints on the end faces or end faces, as described above.
    Another object of the present invention also related to the new trapezoidal fins is a new monolayer sheet which may be in two versions.
    According to a first version, this plate, consisting of a plurality of side by side and parallel to each other flush-mounted and materially interconnected via their longitudinal side edges boards, characterized in that they with a plurality of - materially connected to each other via their oblique longitudinal side edges, in particular glued, lamellas formed - boards, as described above, is formed.
    According to the second version, the single-layer plate with lamellae, characterized in that they have a plate body with about their oblique longitudinal side edges materially connected to each other, alternately longitudinally aligned, materially interconnected, in particular bonded, lamellae according to the variant a described above ), wherein it is provided that in each case one of the two slats according to the above-mentioned variant b) is materially bonded, in particular glued, to the two outer, oblique side flanks at the two lateral edges of the plate body, with its oblique longitudinal side flank.
    Furthermore, with the novel boards formed according to the invention with the "half lamellae" alone and / or combined with conventional boards, e.g. Board width beams are created, which form a further subject of the present invention.
    These beams according to the invention having a plurality of boards stacked on one another and materially connected to one another via their main surfaces are characterized in that they are formed with a plurality of boards material-lockingly bonded to one another via their main surfaces.
    Another essential, but also with the new trapezoidal fins intimately related object of the invention is a new multi-layer plate, which is characterized in that it is formed with a plurality of flat superposed, as previously described, single-layer plates and with - with the same in each case, in particular 1: 1, alternately arranged - conventional single-layer plates with a plurality of about their vertical longitudinal side edges bonded together, conventional boards or lamella boards, all said single-layer plates on their respective main surfaces plate materially together bound, in particular glued, are, is formed and wherein the, in particular 1: 1, alternately arranged, materially bonded surface-bonded single-layer plates each Faserungsverläufe the boards forming them or lamellae, which each substantially perpendicular to each other are fairly aligned.
    Trapezoidal lamellae or individual boards formed therefrom are glued, as previous conical lamellae to a single-layer plate. All Einschichtplatten- conical or trapezoidal lamellae and parallel Einzelbrettern- are used for example in the production of glulam either as a transverse position or longitudinal position. It is advisable to connect the Einschichtplatten at the end faces with a Keilzinkenstoß to an endless plate together. After galvanizing, the endless format is planed in the wide areas. The required lengths for longitudinal and transverse layers are capped from the endless format and supplied to the cross laminated timber production depending on the visual quality either as cover or middle layer.
    Conical slats and single boards made of trapezoidal fins can be used in cross laminated timber instead of parallel prismatic boards. Wherever now parallel prismatic wooden lamellas are used, parallel single boards made of trapezoid conical lamellas can be used to increase the tensile and bending strength. This is also the case in cross laminated timber production, where the single boards are endlessly connected with a finger joint and used as a longitudinal layer as before. Furthermore, parallel single boards can also be used in the production of glued laminated timber.
    In principle, to the properties of conical or trapezoidal lamellae from "sideways" execute the following:
    Basically, the side fabric over the main product, which is cut from the core area, better strength properties under tensile and bending stress. Looking at a parallel prismatic lamella, it is easy to see that the
    Tree fibers are cut from the Besäumkanten. The "cut" fibers reduce the strength of the lamellae.
    Due to the production methods of conical or trapezoidal lamellae, adapted to the growth process and thus the longitudinal fiberization of the tree trunks, it is possible to reduce the number of "cut fibers".
    The course of the fibers is largely parallel to the Besäumkanten a conical lamella.
    The proof of the better tensile strength of single boards made of trapezoidal lamellae compared to parallel prismatic lamellae from the same side fabric is shown in a test report no. PB14-470-1-01 of the University of Graz. The outermost lamellae of the sidewalls of 50 tree trunks were subdivided into three test pieces, with all test pieces having the same dimension.
    The test specimen Z-REF is the reference sample and is parallel-prism cut from side slats.
    The Z-KO test specimen is cut from two conical slats (of the same trunk) glued over the narrow surfaces. The arrangement of the two conical slats hiebei is "mirrored".
    The test specimen Z-KS is a parallel single board made of a trapezoid conical lamella. All three specimens were cut from a tree trunk.
    The test specimens were compared according to ÖNORM EN 4008: 2012. The tensile strength was determined for all three specimens according to ΟΝ- EN 14358. It turns out that the Z-KS test specimens - ie the parallel single boards formed with two half slats - have a higher characteristic characteristic of the tensile strength than parallel prismatic slats.
    Reference to the drawing, the invention is explained in more detail:
    1 shows a hitherto conventional conical lamella and FIGS. 2 and 3 show two possible arrangements of such conventional conical lamellae in the course of their mutual joining and bonding to a single-layer panel, FIG. 4 shows a fascia-conical lamella close to the invention with side flanks, which still has the convex curvature of the tree trunk from which it is cut, Fig. 5 shows the process of creating the oblique, even flat longitudinal side flanks of the new, now trapezoidal, ie according to the invention or inventively used slat, the Fig. 6 and 7 whose plan view, and cross-sectional view, Fig. 8, this slat in an oblique view, Figs. 9 to 12 the process in the manufacture of a
    Plates of two, obtained by longitudinal division of a lamella according to FIG. 9 "half-lamellae", Fig. 13 is a Einschichtplatte according to claim 7 and Figs. 14 and 15, two types of multilayer plates according to the invention, both in an oblique view.
    The conventional "conical" lamella I shown in Fig. 1 has over its entire longitudinal extension from front to rear rising rectangular cross-section Qr, it has here on the visible side a smaller rectangular cross section than the back, the
    Side flank surfaces 13, 14, perpendicular to both - here equal-sized trapezoidal, mutually parallel broad or major surfaces 11,12 of this previously known conical lamella I.
    Referring to Figures 2 and 3, there are two similar types of plate making, as shown in Figure 1, alternately reversed and correct, here equal to side-by-side conical slats I, e.g. by pressure from above and below, see pv, held in position position glued together on their side edges and pressed by both sides lateral horizontal pressure ph to a conventional Einschichtplatte, wherein according to FIG. 2, the rectangular end faces 15, 16 arranged in a transverse plane are.
    According to FIG. 3, the 1: 1 are alternately "inverted" and "correctly" arranged conical lamellae I arranged so that each second of its side edges 13, 14 is aligned at right angles to the two-sided horizontal pressure application direction ph.
    Fig. 4 shows, so to speak, the raw form of a trapezoidal conical lamella 11, as obtained after parallel longitudinal fragmentation of a tree trunk, and which longitudinal side edges 131, 141 which still has the approximately cylindrical curvature of the original tree trunk surface.
    Fig. 5 shows how the convex curved side edges of the Rohlamelle 11 are converted by means of milling heads Fk in flat side edges 13, 14, whereby one, as shown in FIGS. 6 and 7 trapezoidal lamella 1 with a larger trapezoidal face 15 at one and smaller Trapezoidal end face 16 is obtained at the other end thereof, the two wide or major surfaces 11 and 12 are arranged parallel to each other and are connected to each other at an angle α to the same inclined, symmetrically inclined side flank surfaces 13, 14.
    Fig. 8 shows - with otherwise constant reference numerals - the blade 1 in an oblique view.
    Fig. 9 shows the same blade 1 - with otherwise constant
    Reference numerals - but after the longitudinally "vertical" pitch T, which two - here symmetrical - trapezoidal conical half-slats T, 1 "are formed with each unequal-thigh trapezoidal cross-sections Q ', Q". The respective surface designations thereof, namely 11 ', 11 "to 16', 16" are completely analogous to the surface designations 11 to 16 of the lamella 1 according to FIG. 6.
    In Fig. 9 is still a to the main surfaces 11 ", 12" of the (half) lamella 1 "parallel axis of rotation D drawn around which this lamella 1" by 180 °, see arrow, is rotated and in the in Fig. 10 shown "reversed" position is brought.
    Again indicated by an arrow is how the so "inverted" lamella 1 "on the remaining in their position shown in FIG. 9 (half) lamella T is lifted and, as shown in FIG. 11, on the side of the oblique side edge surface 13 'with its now "overhanging" side edge 14 "next to the half-slat 1' is stored.
    Finally, one of the oblique side flank surfaces 13 ', 14 "is provided with a binder, ie adhesive, and after lateral merging and joining of the two half-flaps T, 1", see FIG. 12, an inventive board 2 with main surfaces 21, 22, to the same vertical side edges 23, 24 and end or end surfaces 25, 26, which in each case over its entire length has the same constant (total) Ftechteck cross-section obtained.
    With otherwise constant reference numerals is shown in Fig. 13, as the core region or plate body 30 of a single-layer plate 3 'according to claim 7 of alternately formed "right" and "inverted" trapezoidal conical lamellae, and as each side on both sides one as shown in FIGS. 9 to 12 resulting (half) lamella T, 1 "is arranged.
    Fig. 14 shows - with otherwise constant reference numerals - a multi-layer plate 5 according to the invention, with a plurality of mutually by conventional galvanizing at the end or end faces of their trapezoidal conical slats T corresponding single-layer plates 3 'and a plurality of formed with the single-layer plates 3 '1: 1 alternately with transversely oriented, previously usual boards 200 formed, hitherto conventional single-layer plates 300, wherein the Faserungsverläufe in the Einschichtplatten 3', 300 are aligned substantially perpendicular to each other.
    Finally, FIG. 15 - with otherwise identical reference numerals -also shows a multi-layer panel 5 'according to the invention with a single-layer panel 3 according to claim 6 and one according to claim 4 of two half-panels 1', 1 "according to FIG. 12 formed boards 2 in longitudinal position, which are glued together alternately with one another, as shown in Fig. 13 single-layer plates 3 'with fins 1 and (half) fins 1', 1 ".
    权利要求:
    Claims (9)
    [1]
    claims:
    1. lamellas of natural wood with limited by straight converging longitudinal side edges delimited trapezoidal, mutually parallel broad or principal planes, characterized in that their two mutually parallel principal planes (11, 12, 11 ', 12', 11 ", 12th "), bounded by the converging longitudinal side flanks (13, 14, 13 ', 14", 13 ", 14), the shape of geometrically similar, a) isosceles, or b) unequal leg trapezoids, the lamellae either a) as lamellae (1) with mutually symmetrical, in identical, acute angles (a) in each case to said main planes (11, 12) inclined oblique longitudinal side edges (13, 14), are present and overall longitudinally continuous, in cross section have the shape of geometrically similar, isosceles trapezoids, or b) as lamellas (T, 1 ") each having an inclined at an acute angle (a) to the main planes (11 ', 12', 11", 12 ") inclined Side flank (13 ', 14 ") and one in the right angle to said main planes, arranged vertical longitudinal side edge (14 ', 13 ") is present and overall longitudinally in cross-section the shape of geometrically similar, unequal trapezes (" half-trapezoids ") have.
    [2]
    2. Lamella according to claim 1, variant b), characterized in that - after, preferably longitudinally, longitudinal division of a blade (1) according to claim 1, variant a) - perpendicular to the two main planes (11, 12) and the two end planes (15, 16) in the form of two according to claim 1, variant b) formed lamellae (1 ', 1 ") is present.
    [3]
    3. Slat according to claim 1 or 2, characterized in that the oblique longitudinal side flank (s) (13, 14, 13 ', 14 ") of the slats (1; T, 1") each at an angle (a) of 25 to 70 °, in particular from 30 to 60 °, to the main planes (11, 12; 11 ', 12', 11 ", 12") of the respective lamella (1; T, 1 ") are inclined.
    [4]
    4. board (2), characterized in that it is formed with two blades (1 ', 1 ") according to claim 1, variant 1b) or claim 2, wherein one of these two blades (T, 1") after 180 ° - Twisting about an axis of rotation (D) running in the direction parallel to its two principal planes (11 ', 12') via their oblique longitudinal side flanks inclined at an angle (a) to their principal planes (1T, 12 ', 11 ", 12") (13 ', 14 ") materially connected to each other, in particular glued, and the board (2) thus longitudinally consistently uniform rectangular cross-section.
    [5]
    5. Endless board (2 '), characterized in that it is formed with, preferably via flat or Vertikalkiltzinkverbindungen at their end or end faces (25, 26), longitudinally closed to each other, individual boards (2) according to claim 4 ,
    [6]
    6. Single-layer plate (3) of a plurality of juxtaposed and parallel to each other flush-mounted and materially interconnected via their longitudinal side edges boards, characterized in that they with a plurality of - with their oblique longitudinal side edges (23, 24 ), in particular adhesively bonded, lamellae (Γ, 1 ") formed - boards (2) according to claim 4 is formed.
    [7]
    7. Single-layer plate (3 ') with lamellae (1), characterized in that - they have a plate body (30) connected via their oblique longitudinal side edges (13, 14) materially connected to each other, alternately longitudinally aligned, materially interconnected , in particular glued, lamellae (1) according to claim 1, variant a) is formed, and - that at the two outer, oblique side edges at the two lateral edges of the plate body (30) each one of the two blades (1 ', 1 " ) according to claim 1, variant b), or claim 2, with its oblique longitudinal side edge (13 ', 14 ") bonded materially bonded, in particular glued, is.
    [8]
    8. bar (4) having a plurality of layers stacked on their major surfaces materially interconnected boards, characterized in that the same with a plurality of each of their major surfaces (21, 22) materially bonded together boards (2) according to claim 4 formed is.
    [9]
    9. multi-layer plate (5), characterized in that it with a plurality of single-layer plates (3 or 3 ') according to claim 6 or 7 and - with the same in each case, in particular 1: 1, alternately arranged - conventional single-layer plates (300) with a plurality of about their vertical longitudinal side edges (213, 214) bonded together, conventional boards (200) is formed, all said single-layer plates on their respective main surfaces plate materially bonded to each other, in particular glued, are formed are and in which, in particular 1: 1, alternately arranged, materially bonded surface-bonded single-layer plates (3, 3 ', 300) respectively Faserungsverläufe the forming boards or lamellae, which are each aligned substantially perpendicular to each other.
    类似技术:
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    同族专利:
    公开号 | 公开日
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE2159337A1|1971-11-30|1973-06-07|Albert Rufle|METHOD AND DEVICE FOR MANUFACTURING SAW WOOD|
    WO1993008000A1|1991-10-16|1993-04-29|Hammarstroem Lars|Method for reducing a log|
    AT11958U1|2010-09-07|2011-08-15|Hans-Peter Ing Leitinger|PROCESS FOR PROCESSING RAW ROUNDWOOD AND WEDGE-LINKED WOOD COMPOSITE PRODUCTS|DE102020120386A1|2020-08-03|2022-02-03|Xaver Haas|Method of making structural lumber from small wood|
    法律状态:
    2017-08-15| REJ| Rejection|Effective date: 20170815 |
    优先权:
    申请号 | 申请日 | 专利标题
    AT112015|2015-01-09|EP16150534.2A| EP3042744A1|2015-01-09|2016-01-08|Lamellae made of natural wood, planks, beams and panels produced with same|
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