Classifications

• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27M—WORKING OF WOOD NOT PROVIDED FOR IN SUBCLASSES B27B - B27L; MANUFACTURE OF SPECIFIC WOODEN ARTICLES
  • B27M1/00—Working of wood not provided for in subclasses B27B - B27L, e.g. by stretching
  • B27M1/02—Working of wood not provided for in subclasses B27B - B27L, e.g. by stretching by compressing
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B27—WORKING OR PRESERVING WOOD OR SIMILAR MATERIAL; NAILING OR STAPLING MACHINES IN GENERAL
  • B27D—WORKING VENEER OR PLYWOOD
  • B27D1/00—Joining wood veneer with any material; Forming articles thereby; Preparatory processing of surfaces to be joined, e.g. scoring
  • B27D1/04—Joining wood veneer with any material; Forming articles thereby; Preparatory processing of surfaces to be joined, e.g. scoring to produce plywood or articles made therefrom; Plywood sheets
  • B27D1/08—Manufacture of shaped articles; Presses specially designed therefor
  • B27D1/083—Presses specially designed for making the manufacture of shaped plywood articles
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B30—PRESSES
  • B30B—PRESSES IN GENERAL
  • B30B15/00—Details of, or accessories for, presses; Auxiliary measures in connection with pressing
  • B30B15/02—Dies; Inserts therefor; Mounting thereof; Moulds

Definitions

• the present invention relates to a method of forming wood, in particular for the production of wooden objects by pressure.
• the pressing of wood is a technique for producing known wooden objects.
• This technique consisting in exerting a strong force against the surface of a wooden blank, often placed in a mould, makes it possible to compress the wood in order to give it a predefined shape, while increasing the resistance of the object due to its densification.
• This technique also has the advantage of allowing the production of hollow shapes that cannot be milled, for example polygonal shapes with sharp angles, which is not possible by milling because of the diameter of the milling head.
• EP1706248 describes a wooden object such as a casing for an electronic device obtained by compression of a previously machined blank (for example by milling).
• a previously machined blank for example by milling.
• the bottom of the die (or mould) in which the blank is placed is strongly curved in order to avoid the problems of demoulding as well as of sharpness of the contours of the final object.
• the part requires prior machining, for example milling, of a cavity whose depth will simply be reinforced by pressing. Only the bottom of the cavity is subjected to compression; on the other hand, the upper surface of the blank does not undergo any deformation under the action of the forming press.
• the aesthetic appearance of the outer and inner edges of the object is determined mainly by milling.
• An object of the present invention is to provide a method of forming a wooden object free from the limitations of the methods known in the prior art.
• Another object of the invention is to provide a method for forming a wooden object which is ecological and economical.
• Another object of the invention is to provide a method for forming a wooden object which makes it possible to quickly obtain particularly clean side and front faces and sharp edges.
• Another object of the invention is to provide a method for forming a wooden object which makes it possible to quickly obtain sidewalls resistant to shocks and to humidity.
• the pressure during the pressing is greater than 1.5*10 6 N/m 2 , in that the pressing is carried out cold, in that the pressing is carried out dry, and in that the die comprises a positioning flank bearing against the blank during the pressing and forming a first angle not exceeding 5° with the fibers of the wood of the blank positioned in the die, and/or in that the forming press comprises a punching flank resting against the blank during pressing , the second punching flank forming a second angle not exceeding 5° with the fibers of the wood of the blank positioned in the die.
• the pressure during pressing is preferably greater than 2*10 6 N/m 2 , preferably greater than 5*10 6 N/m 2 .
• the punching flank can slide along the fibers of the blank during pressing, without participating in their longitudinal compression, or only in a very limited way if the punching flanks are not parallel to the fibers.
• the entire punching flank and the positioning flank slide along the fibers of the blank during pressing. [0015]
• the compression parallel to the fibers of the wood confers advantages on the resulting object.
• the faces, the edges and the contours of the final object are particularly sharp because they are defined by the fibers of the wood which are compressed on themselves, but retain their rectilinearity.
• flanks In the case of punching and positioning flanks parallel to the fibers of the wood during pressing, the side faces of the object along these flanks are defined by the lateral surface of contiguous compressed fibers, without the ends of the fibers do not appear on these faces.
• the blank does not require the prior machining of a cavity or a concave housing.
• the concave portion(s) of the part can be obtained solely by pressing, without prior machining.
• the pressure greater than 1.5*10 6 N/m 2 preferably greater than 2*10 6 N/m 2 , preferably greater than 5*10 6 N/m 2 , makes it possible to obtain objects having sharp faces and edges, including objects with a polygonal profile or cavity.
• a pressure greater than 1.5*10 6 N/m 2 makes it possible to compress at least 50% of the height (in the direction of the wood fibers) of the blank for wood species.
• the height of the blank can be compressed by a maximum of 50% without the final object suffering.
• an even greater compression can be exerted without damage, for example for wood with a density of 0.4 kg/dm 3 , the maximum height of the blank can be compressed by 60% without affecting to the integrity of the object.
• the form press and the die may comprise sliding guide flanks against one another during pressing.
• the guide flank(s) advantageously make it possible to maintain the die with precision during pressing, to guarantee controlled deformation and precision forming.
• the blank is thus immobilized at the time of pressing.
• a guide flank of the die can guide the forming press during pressing, thus contributing to obtaining clean flanks of the compressed parts.
• the pressing step can be carried out using a molding press comprising a first flank perpendicular to the fibers of the wood, and a second flat flank, the two flat flanks being joined by the punching flank.
• the pressing step may comprise a phase of guiding the form press, the guiding flank of the die guiding the form press.
• the guide flanks are advantageously parallel to the pressing direction.
• the guide flanks are advantageously parallel to the longitudinal direction of the wood fibers.
• a maximum height of the blank in the direction of the wood fibers can be reduced during pressing.
• the height of the guide flank of the die may be greater than the maximum height of the blank before pressing.
• the first surface, the second surface, and/or a bottom of the matrix can be structured.
• the minimum resolution of the relief of the structuring can be very fine, that is to say between 10 ⁇ m and 50 ⁇ m, thus allowing the production of very fine structures on the surface of the wood.
• the punching flank may comprise a first chamfer making it possible in particular to smooth the inner flank/inner bottom transition of the object produced.
• the first chamfer can form an angle with a bottom surface of the die of at most 35°.
• the positioning flank of the die may comprise a second chamfer making it possible in particular to smooth the transition from the outer flank/outer bottom of the object produced.
• the second chamfer can form an angle with a bottom surface of the die of at most 55°.
• the form press can comprise a transverse or longitudinal stepped profile, in particular making it possible to approximate curves that are difficult to achieve.
• the pitch of the staircase can be very fine, typically between 0.01 mm and 0.2 mm.
• the method may include a step of extracting the blank so as to separate the blank from the die and/or from the molding press after the step of pressing the blank.
• the blank may have a density before pressing of less than 0.75 kg/dm 3 , preferably less than 0.5 kg/dm 3 .
• the wood from which the blank is cut can be chestnut, okoumé, stone pine, linden, alder, poplar, balsa, spruce, fir, maple, walnut, ash or beech.
• a step of mechanical machining of the blank can be introduced before the pressing step to increase its porosity and reduce its density.
• the mechanical machining may include several micro-drillings in the direction of the wood fibers.
• the micro-drillings can be made by means of a drill, or by stamping, for example by means of needles pressed simultaneously in a direction parallel to the fibers of the wood.
• One end of the form press in contact with the blank may comprise a bevelled profile.
• FIG. 1 illustrates possible cuts of a blank in a block of wood.
• FIG. 2 illustrates a matrix containing a blank of wood.
• FIG. 3a illustrates a pressing step in which a form press is brought against a blank in a die.
• FIG. 3b illustrates a pressing step in which the form press has compressed part of the blank.
• - Figure 4 illustrates a cross section of a die containing a blank of wood, the positioning side of the die being inclined.
• - Figure 5 illustrates a cross section of a die containing a blank of wood and a molding press, the positioning flank of the die and the guide flank of the press being inclined.
• FIG. 6 illustrates a cross section of a form press having a punch with an inclined punching flank.
• FIG. 7 illustrates a cross section of a die with a particular housing containing a blank of wood.
• FIG. 8 illustrates a cross section of a form press having a particular profile with two punches.
• FIG. 9 illustrates a cross section of a matrix whose bottom is structured.
• FIG. 10a illustrates a cross section of a form press before pressing allowing various pressures on the surface of a blank.
• FIG. 10b illustrates a cross section of a form press after pressing allowing various pressures on the surface of a blank.
• FIG. 11a and 11b illustrate form presses with a chamfer.
• - Figure 12 illustrates a die whose bottom has a chamfer.
• - Figure 13 illustrates two positions of a form press extraction device after pressing.
• FIG. 14a illustrates a form press, one side flank of which comprises a stepped portion.
• FIG. 14b illustrates a bottom view of a form press whose profile has stepped portions.
• Figures 15a and 15b illustrate form presses comprising several punches.
• the present invention relates to a method of forming a wooden object by compression of a blank, the compression being carried out in a direction parallel to the fibers of the wood.
• Examples of wooden objects that can be obtained by the process of the invention include, for example, toys, cutlery handles, decorative objects, crockery, boxes, boxes for watches, jewelry boxes, containers or packaging for cosmetic products, items of clothing or fashion such as buttons, shoe soles, etc.
• the present method is particularly suitable for containers of viscous products such as ointments, creams, or even liquids.
• the densification resulting from pressing reduces the porosity of the wood, thus giving it sufficient impermeability to contain viscous or liquid products.
• the risk of transfer of molecules from the wood to a material in contact or vice versa is low because the transport channels are closed.
• wood is naturally a noble material with antibacterial potential, pleasant to the touch and often having a pleasant smell.
• Figure 1 illustrates examples of possible cutting of a blank 11 in a piece of wood 10.
• the cutting is carried out along cutting lines 12 in a direction transverse to the fibers of the wood in order to allow compression parallel to the fibers wood later.
• transverse is here to be understood in the sense of “non-parallel” Le., the angle between the cutting lines 12 and the fibers of the wood is non-zero.
• the blank 11 obtained by cutting is then positioned in or by a die 20.
• This die has a positioning flank 21 resting against the blank.
• the blank is positioned inside the die, so that one of the faces of the blank transverse to the fibers of the wood is free and so that the positioning side and the bottom of the matrix surround the blank on the rest of its surface.
• the positioning of the blank can consist of a simple placement of the blank by the open part of the die intended to guide the forming press or, in certain more complex embodiments, the blank can be introduced laterally into a housing of the matrix.
• FIG. 7 where the geometric constraints of the blank require that it be placed in the die 20, for example by sliding in a direction perpendicular to the pressing direction. It is also possible to position the blank by means of an opening machined in the blank, or clampable die parts.
• this blank is pressed by a form press 30.
• the direction of pressing is parallel to the wood fibers of the blank.
• the molding press is placed against the free face of the blank and pressure is exerted on the molding press so as to deform the blank until reproducing in negative all or part of the volume of the molding press and/or of the die in the blank.
• a characteristic of the present method consists in that the pressing is carried out cold and dry. Hot pressing reduces the pressure force required to deform the wood.
• the increase in the temperature of the wood contributes to its drying out, resulting in a greater sensitivity to deformations, in particular to shrinkage which must then be compensated or to cracks.
• Such compensation can be facilitated by steaming the wood before pressing or via a shrink die in certain directions.
• these steps complicate the process and thus make it more expensive.
• Dry pressing also means that the wood blank requires no soaking before pressing, typically no soaking in a hardening resin or no steaming.
• the molding press comprises a punching flank 303 resting against the blank during pressing.
• Figure 3a illustrates a first step of this method in which the blank 11 has been positioned in the die 20 bearing against the positioning side 21 and a form press 30 is moved in the direction of the free surface of the 'draft.
• Figure 3b illustrates a second step in which a central portion of the form press 30 has compressed the blank 20 until a recess is obtained relative to the side portion of the blank.
• the mold press 30 is mechanically brought against the free surface of the blank 11.
• the die can be provided with a first guide flank 24 to guide the form press.
• This first guide flank may consist, in a preferred embodiment, of a portion of the positioning flank 21. the surface used to guide the form press.
• a function of this first guide flank 24 is to guarantee precise guidance of the molding press during pressing with respect to the die and the blank.
• the forming press may also include a second guide flank 32 which slides against the first guide flank 24 and/or against the positioning flank of the die during the movement of the die. form press 30.
• the diameter of the form press at the level of the second guide flank is slightly smaller than the internal diameter of the die at the level of the first guide flank of the die so to leave a gap between 0.01 mm and 0.5 mm necessary for the extraction of the object after pressing.
• the positioning side 21 of the die is, ideally, parallel to the direction of the wood fibers.
• at least one positioning flank of the die can be slightly inclined at a first angle ⁇ with respect to the fibers of the wood so as to form a truncated cone whose the widest diameter is at the level of the free face of the blank.
• This first angle a can reach a maximum of 5° with respect to the direction of pressing, that is to say the direction of the fibers of the wood of the blank when it is is positioned in the matrix.
• the die comprises an inclined positioning flank as described above in order to facilitate demoulding and an essentially vertical guiding flank in the extension of the positioning flank to guarantee the guidance of the press during pressing.
• the play between the first positioning flank 21 and the blank is preferably very small before pressing, in order to allow the insertion of the blank into the die but to guarantee its immobilization during pressing while avoiding lateral deformations.
• this clearance is preferably less than 0.5mm.
• the form press 30 illustrated in Figure 5 comprises a second guide flank 32 which is, similarly to the positioning flank 21, inclined at a third angle P with respect to the direction of compression so as to adapt to the inclination of the positioning side.
• the third angle P can reach a maximum of 1° with respect to the pressing direction.
• Figure 5 illustrates an embodiment in which the guide flank of the form press 32 forms an angle P so as to correspond to the inclination of the positioning flank 21.
• a die respectively a forming press, with one or more positioning flanks, respectively guiding, which are inclined, and at least one other positioning flank, respectively guiding, parallel to the fibers of the wood and thus effectively allowing the form press to be guided against the die throughout its movement.
• the inclination of the second guide flank 32 of the press at an angle P relative to the fibers of the wood makes it possible, for example, to facilitate the demolding of the blank after the pressing step.
• this inclination excludes guidance of the forming press in the die because from the moment when the second guiding flank of the forming press comes into contact with the first guiding flank 24 of the die, the vertical movement of the press in the direction of the blank is prohibited.
• the die 20 is removable in order to facilitate the demolding of the wooden object after pressing.
• the matrix can be provided with extractors also making it possible to facilitate the demolding of the object.
• a stripping support can be arranged above the die, as illustrated in FIG. to the die and parallel to the pressing axis making it possible to press on an upper lateral portion of the die so as to mechanically remove the die containing the pressed blank from the form press.
• the movable rods are replaced by a holding ring making it possible to press on the blank when the mold press is withdrawn so as to extract the mold press from the blank.
• the second punching flank 32 on the form press 30 forms a second angle y with the fibers of the wood.
• this angle can vary between 0° and 5°.
• the profile of the forming press at the level of its punching flank can be slightly conical as illustrated in FIG. 6. This second angle also makes it possible there to obtain a higher quality of the internal surface of the wooden object.
• extractors can be used to remove the object from the die after pressing.
• These extractors consist for example into modular elements of the die or form press.
• the angle y is equal to 0°, it is preferable to add extractors.
• the form press 30 comprises a first flat surface 301 perpendicular to the fibers of the wood when the blank 11 is positioned in the die 20 and a second flat surface 302 interconnected by the punching flank 303 of the form press.
• the first flat surface and the punch flank together form a punch determining the shape and/or the compression volume of the blank.
• the first flat surface 301 is the first part of the molding press to come into contact with the blank and then penetrates inside the latter under the effect of the pressure.
• the molding press 30 comprises several punches making it possible to produce several distinct indentations in the blank 11.
• Each punch comprises a first flat surface 301 perpendicular to the fibers of the wood when the 'blank is positioned in the die, a second planar surface 302 as well as a punching flank 303 connecting the first planar surface to the second planar surface.
• FIG. 15a and 15b illustrate mold presses provided with several punches, for example three punches, the width of which can vary. The punches are thus delimited either, laterally, by the punching flank 303 of the molding press, or by recesses 305 of the molding press.
• the minimum resolution of the wood for pressing with a form press comprising several punches is between 0.1 mm and 10 mm, preferably between 0.5 mm and 8 mm, typically between 1 mm and 5 mm. This resolution depends on several parameters, such as the type of wood and/or the pressing depth.
• FIG. 15a illustrates a form press with a resolution of the order of 3mm, that is to say that the width of the recesses 305 is approximately equal to 3mm.
• FIG. 15b illustrates an embodiment in which the resolution is approximately 2mm and in which the recesses are particularly off-center with respect to the center of the form press.
• the geometry of the lower portion of the punching flank 303 of the molding press 30, that is to say the portion first coming into contact with the blank during pressing, is particularly important with regard to the sharpness of the sides and the bottom/side transition of the piece of wood resulting from the pressing.
• the punching flank forms a sharp angle with the portion of the form press perpendicular to the fibers of the wood.
• the punching flank 303 can also be provided with a chamfer 304 in order to obtain a corresponding chamfer on the blank after pressing.
• a chamfer is typically used to smooth the flank/bottom transition of the part obtained after pressing the blank.
• the transition between the vertical flanks and the bottom surface of the die 23 typically has a sharp angle with a chamfer of at most 35°, preferably at most 30°.
• the punching flank 303 can also be provided with a rounding, the angle of which with the bottom surface of the die does not exceed 35°, preferably 30°.
• the guide flank 303 may also include a chamfer on an upper portion, so as to produce a chamfer on an outer shape of the blank during pressing.
• the chamfer angle can typically be up to 50°.
• the positioning flank 21 of the die may also include a chamfer 211 at the positioning flank/bottom surface transition of the die.
• Such a chamfer 211 makes it possible in particular to facilitate the extraction of the blank from the die after pressing. It also makes it possible to obtain a clear transition between the outer sides of the blank and the outer surface of the bottom of the blank.
• Chamfer 211 typically forms an angle with a bottom surface of the die of at most 55°, preferably 45°.
• the punching flank 303 of the form press 30 may comprise a stepped profile whose pitch is relatively small compared to the size of the mold. 'draft.
• a stepped profile makes it possible in particular to approximate a curve, the production of which by pressing can be complex, without altering the visual rendering. It also makes it possible to improve the sharpness of certain flank/bottom transitions of the blank.
• the profile of the transition between the punching flank and the lower part of the form press comprises a staircase whose pitch, that is to say the width d stair tread is between 0.01mm and 0.2mm.
• the stair treads are thus perpendicular to the wood fibers of the blank when it is in the die.
• the guide flank comprises a stepped profile, the steps of which are parallel to the fibers of the wood of the blank.
• Figure 14b illustrates a stepped profile of the form press obtained by cutting along a plane orthogonal to the wood fibers of the blank in the die.
• the sharpness of the flanks may depend on the pressing speed. In general, a high pressing speed makes it possible to obtain sharper sidewalls. This speed is typically between 4mm/s and 180mm/s.
• the blank 11 can be compressed over its entire free surface or over one or more predefined zones corresponding to the geometry of the mold press.
• the maximum height H of the blank in the direction of the wood fibers can be reduced after pressing if the entire blank is compressed.
• the maximum height H of the blank in the direction of the wood fibers can remain identical after pressing if only one zone of the blank is compressed.
• the blank has a maximum height before pressing H while, as shown in Figure 3b, the blank has a maximum height after pressing H 'and a minimum height after pressing H ". In all the cases the following relations are always verified:
• the pressing step can be performed by exerting continuous pressure from the forming press 30 on the free surface of the blank so as to compress the entire desired height in one go.
• the pressing step can be carried out by exerting a hammering, that is to say, a succession of pressures of the mold press against the free surface of the blank.
• the hammering allows a reduction in the pressure force necessary to press a similar height, and/or a densification of the wood to a greater depth.
• the blank or the die or the forming press can be subjected to vibrations, for example to vibrations in the longitudinal direction of the fibers of the wood at a frequency between 1 Hz and 1 MHz, in order to to put it in vibration and to facilitate the compression of the blank by the forming press.
• vibrations facilitate the penetration of the form press into the wood, facilitate the sliding of the fibers against each other, and can contribute to softening it by heating it slightly during pressing.
• subjecting the blank to these vibrations allows a reduction in the pressure force necessary to press a similar height, and/or a densification of the wood to a greater depth.
• the structuring corresponds to the creation of a relief by pressing on a portion of the blank, this relief being comparatively small compared to the size of the blank.
• the reliefs obtained by structuring typically have a minimum resolution of the order of the size of the channels conducting the water in the wood, that is to say of between 10 ⁇ m and 50 ⁇ m.
• the depth of the structuring relief in the pressing direction is less than the displacement distance of the molding press in the blank.
• the depth of the structures in the direction of pressing can be less than 2mm.
• the die press is structured so as to negatively print the pattern on the blank during pressing.
• the bottom surface of the die is also structured so as to negatively print the pattern on the outer surface of the blank in contact with the bottom of the die.
• the structuring allows, among other things, the production of logos, brands, texts, patterns as well as particular texturing which may have a physical or aesthetic function.
• a structured element can be arranged between the forming press and the blank, or between the blank and the bottom surface of the die, so that during pressing, the pattern of the element structured is reproduced in negative on the draft.
• the structured element can be for example a fabric, a piece of leather, a piece of paper, a tree leaf, etc.
• a first pressing step makes it possible to form the blank, in particular the flanks, then, a second pressing step makes it possible to structure portions of the formed blank.
• the part of the mold press in contact with the blank during pressing can be structured so as to produce a negative or positive image on the blank.
• the first planar surface and/or the second planar surface of the forming press can be structured.
• Figure 9 illustrates an embodiment in which the die, in this case a bottom surface of the die 23 opposite the free surface of the blank, may also be patterned in order to obtain a positive or negative pattern on the face of the blank opposite to its free face.
• This structuring of the form press and/or of the die makes it possible to combine the pressing of a blank with the aim of forming a wooden object and the negative or positive printing of a pattern.
• the structures can comprise for example an image, a pattern, a logo, a text, ribs, grooves, etc, on the surface of the press of form in order to be printed in negative in the blank .
• the species of wood chosen for the blank has a considerable influence on the pressing parameters and the variety of objects that can be produced.
• the denser the wood the greater the force of pressure to be exerted to compress it by a given height.
• the lower the density of the chosen wood the greater the compression can be and therefore the greater the compressed volume.
• the blank is cut from a wood having a density of less than 0.75 kg/dm 3 , preferably from a wood having a density of less than 0.5 kg/dm 3 .
• Suitable species of wood are for example poplar or linden (approximately 0.5 kg/dm 3 ), spruce (approximately 0.45 kg/dm 3 ), balsa (approximately 0.14 kg/dm 3 ).
• Other species such as chestnut, maple, beech, fir, okoume, stone pine or alder are also particularly suited to the scope of the present invention. The list of these species is in no way limiting, the present pressing process operating with wood species having a density ranging up to 0.75 kg/dm 3 , or even up to 0.85 kg/dm 3 .
• a preliminary step of mechanical machining of the blank can be carried out.
• a series of micro-drillings is carried out using a drill, or by stamping with needles, so as to reduce the density of the blank before pressing.
• the holes thus drilled by micro-drilling are filled during compression.
• the resulting object can be made sufficiently tight to contain viscous products (creams, pastes, etc.) or even liquids.
• the method of the invention can also be used to manufacture objects which do not have concave portions on their upper face, but also only convex portions.
• the method is used to make wooden game pieces, such as interlocking building bricks.
• the end of the molding press that first comes into contact with the blank during pressing has a beveled and/or sharp profile so as to facilitate its penetration into the wood.
• a profile also makes it possible to obtain sides of the wooden object that are clean after pressing and to avoid any sanding work after pressing.
• the present method can also be applied to assemble by pressing a second wooden blank to the first blank.
• a second blank is placed between the first draft and the form press.
• the two blanks are then assembled together during the pressing step under the effect of the pressure exerted by the forming press.
• the assembly of the two blanks can be facilitated by prior pressing of two corresponding profiles on each of the faces of the blanks intended to be in contact with the other.
• the direction of the fibers of the wood of the first blank is always parallel to the direction of pressing
• the direction of the fibers of the wood of the second blank can be parallel, perpendicular or oblique with respect to the direction of pressing. .
• This latitude makes it possible to create interesting patterns on the final object as well as either to facilitate pressing by reducing the pressure necessary to compress the two blanks, or else to obtain a particularly resistant final object. It is also possible to combine wood species of different densities and different compressive strengths.
• the assembly of two parts obtained by the pressing process can also be obtained after the pressing of each part, for example using tenons and/or mortises.
• the part intended to be inserted into the other can be dried before its insertion; by taking up humidity from the surrounding air, it will tend to expand to strengthen the tenon-mortise connection.
• the pressing method of the present invention can also be applied to a blank resulting from the bonding of two or more pieces of wood in order to allow the pressing of larger blanks.
• Gluing can typically be done in the direction of the wood grain of the two pieces.
• the pressing strength of a glued blank is essentially the same as an unglued blank. Moreover, the glue lines are practically invisible after pressing.

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• Engineering & Computer Science (AREA)
• Life Sciences & Earth Sciences (AREA)
• Mechanical Engineering (AREA)
• Wood Science & Technology (AREA)
• Forests & Forestry (AREA)
• Manufacturing & Machinery (AREA)
• Dry Formation Of Fiberboard And The Like (AREA)
• Chemical And Physical Treatments For Wood And The Like (AREA)

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• 2021
  • 2021-09-24 CH CH70308/21A patent/CH718995A1/fr unknown
• 2022
  • 2022-09-23 KR KR1020247013275A patent/KR20240073909A/ko active Pending
  • 2022-09-23 AU AU2022351701A patent/AU2022351701A1/en active Pending
  • 2022-09-23 JP JP2024518675A patent/JP2024533708A/ja active Pending
  • 2022-09-23 EP EP22786476.6A patent/EP4405149B1/de active Active
  • 2022-09-23 CN CN202280069683.9A patent/CN118215562A/zh active Pending
  • 2022-09-23 ES ES22786476T patent/ES3063096T3/es active Active
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