EP0462586B1

EP0462586B1 - Woody board

Info

Publication number: EP0462586B1
Application number: EP91110039A
Authority: EP
Inventors: Yusho Nakamoto
Original assignee: Juken Sangyo Co Ltd
Current assignee: Juken Sangyo Co Ltd
Priority date: 1990-06-19
Filing date: 1991-06-19
Publication date: 1999-08-25
Anticipated expiration: 2011-06-19
Also published as: JP3038488B2; EP0462586A3; DE69131547D1; AU7914991A; EP0462586A2; KR920000447A; KR0183985B1; CA2044865C; DE69131547T2; CA2044865A1; AU653529B2; JPH0452102A; NZ238616A

Description

The present invention relates to a woody board, which has a sufficient mechanical strength as a woody material and which has a smooth surface.
Various simplex boards to be prepared by separately shaping a wood powder, woody fibers or wood chips, optionally along with a binder, under pressure have heretofore been known, but a composite board composed of a plurality of such simplex boards is unkown.
A wood powder and woody fibers are well known in this technical field. Briefly, the former is one to be obtained by finely pulverizing wood like sawdust; and the latter are ones to be obtained by disintegrating wood into fibers. Wood chips in this case are also known, which are obtained by shaving or cutting a wood bar from the top end thereof, with the bar being rotated in such a way that a pencil is shaven, into chips each having a size of about 1.5 mm or less as the thickness, about 30 mm or less as the width and about 100 mm or less as the length. Examples of molded boards made of such woody material will be mentioned. As an example of simplex boards made of a wood powder, there is known a particle board; as examples of simplex boards made of woody fibers, there are a hard board, a middle density fiber board (MDF) and an insulation board; and as examples of simplex boards made of wood chips, there are a strand board and an oriented strand board (OSB).
These boards have both merits and demerits, and they often cause some inconvenience in actual use thereof.
In manufacturing stairs, service counters, doors and the like, substrates which have a sufficient thickness and a sufficient mechanicl strength and which have a smooth surface capable of being covered with a decorative sheet and with screw-drawing resistance are needed, but the above-mentioned simplex boards could not be used as such substrates. Of these boards, a hard board may be mentioned to have a relatively high mechanical strength and a relatively satisfactory surface smoothness. However, it is impossible to obtain a hard board having a sufficient thickness. Additionally, since a hard board is prepared by a wet method, it has a large specific gravity and is therefore defectively extremely heavy. Further, screws can hardly be applied to a hard board and the board has a low screw-drawing resistance value.
It may be considered to laminate an MDF having a sufficient surface smoothness onto the both surfaces of a strand board or OSB, but adhesion between them would be poor and unstable since the strand board and OSB have a poor surface smoothness. Even if they could be laminated, the resulting laminate product has a problem in that the laminating cost is high since double lamination is necessary. In addition, as an MDF has low mechanical strength, it is difficult to prepare a satisfactory thin MDT. As a result, where both surfaces of a strand board or OSB are laminated with a thick MDF by double lamination, the resulting laminate would thereby have a lowered mechanical strength, disadvantageously.
In addition to the above-mentioned boards, where a plywood or LVL (laminated veneer lumber) is made from a coniferous tree material, there occurs a problem that the woody product of the prior art could hardly have a smooth surface. This is because when a coniferous tree material is formed into veneers, in general, the surfaces of them often have knots and cracks. There are few coniferous trees which have no drawback, like lauan and other trees from the South Sea Islands. Though there would be some knot-free good tree materials to be derived from coniferous trees, the amount of them is small and the cost thereof is high. Additionally, even defectless coniferous tree materials often give shaped articles having uneven surfaces because of the pressure as applied thereto for shaping under pressure, since the hardness of them is not constant but varies depending upon the winter-grown part being hard and the summer-grown part being soft.
Under the situation, in order to overcome the problems, there have been proposed a patching method of holding the knot parts in the surface veneer followed by embedding wood patches into the holed parts and a method of laminating a woody material having a smooth surface, such as an MDF (middle density fiber board) to the both surfaces of a substrate woody material. However, the former patching method causes a disadvantageous drawback that the outward appearance of the patched surface is bad due to the existence of embedding traces. Even though an additional thin decorative paper or decorative veneer is laminated as a secondary lamination so as to cover the patched surface, such an unfavorable outward appearance of the patched surface would still appear through the surface of the covered decorative paper or veneer.
On the other hand, the latter method also has a troublesome problem that the mechanical strength of the resulting laminate board is low, because of the following reasons. In general, an MDF could not be thinner than 3 mm, as too thin MDF sheets would curve owing to insufficiency of the strength of them. Therefore, even when the thinnest known MDF sheet having a thickness of 3 mm is laminated to the both surfaces of a substrate of woody material by the known method, and with the plywood having a total thickness of the two laminated MDF's, that is to say of 6 mm, the mechanical strength of the plywood is lowered relative to the thickness. In this connection, if an MDF sheet is laminated onto only one surface of a substrate, the resulting plywood laminate is also disadvantageous as it is often warped.
A prior art that is of interest is FR-A-2 568 510 that discloses two ways of manufacturing a laminate. According to the first way two layers of adhesively bonded particles are laid down as molded layers by extruding devices, one of the layers being extruded onto the top of the other layer. Then a wooden core, that can comprise a plurality of layers, is added on top. Thereafter two more layers, similar to the first two layers, are added by extruding devices. The resulting composite structure is then pressed together between heated platens. In the finalized product the outer extruded layer can be of a quality more suitable for the smoothness of the outer faces than the quality of the extruded layers that are in direct contact with the wooden core. According to a second method only a single extruded layer of adhesively bonded particles is applied to each of the two faces of a central wooden core and the resulting composite is then pressed together between heated plates. This prior art gives no teaching of creating conditions such that the molded layers can be of reduced thickness compared with that of the wooden core to provide optimum conditions but merely states that in the second embodiment all three layers are of substantially the same thickness.

Objects of the present invention

One object of the present invention is to provide a woody board, which has good physical properties with respect to the mechanical strength, the surface smoothness and the screw-drawing resistance value and which is prepared at a low manufacture cost.
Another object of the present invention is to provide a method of preparing a woody board which has good physical properties with respect to surface smoothness, screw-drawing resistance value and mechanical strength.
Still another object of the present invention is to provide a method of preparing the woody board of the present invention.
A woody board of the present invention comprises an integrally molded layer of woody fibers provided on one surface or both surfaces of a woody substrate of plywood;
wherein said woody substrate consists of several sheets of tree veneer laminated to form said substrate; and in which
said molded layer of woody fibers is one that has been pressed and molded onto said substrate;
said substrate consisting of five layers of a coniferous wood; the substrate having a thickness of 12,5 mm; and the molded layer being in the form of a middle density fiber board having a thickness of 3mm or less.
In the above defined woody board the thickness of the molded layer of woody fibers can be 1 to 2mm.
The woody board may be one provided with said molded layer on both surfaces of the woody substrate and pressed so as to integrally form a middle density fiber board having a thickness of 1mm; and wherein each molded layer is laminated with a decorative veneer.
The woody substrate can be a coniferous tree plywood or a coniferous laminated veneer lumber comprising five coniferous tree strips pressed together in a direction perpendicular to the fibrous direction of each strip.
The thickness of each veneer may be 2.5mm.
The woody board may have said molded layer of woody fibers on one surface only of said woody substrate and the resulting woody board may have an arrow height warp of 1.5mm at the center of a length of 185Omm.
According to the method of the present invention a woody material mix obtained by blending an adhesive and woody fibers is molded on at least one surface of a woody substrate of a coniferous tree plywood;
the woody substrate being made from five sheets of a coniferous tree veneer that are laminated to form a substrate having a thickness of 12.5mm;
and wherein the or each layer of woody material mix is pressed and moulded onto said substrate to create a middle density fiber board having a thickness of 3mm or less.
The woody material mix may be applied to the woody substrate by a hot-pressing method.
The hot-pressing method may be a hot plate-pressing method.
The hot-pressing method may be a hot roll-pressing method.
In preparing the woody board of the present invention, it is desired, if possible, that the woody substrate and the molded layer of woody fibers are pressed simultaneously under heat and pressure.
The coniferous tree plywood or LVL may be either in the form of a previously shaped one or in the form of a combination of plural veneers as merely piled up prior to being shaped into a plywood.
The raw material of a board to be used in the present invention, which comprises a woody material of woody fibers and an adhesive, may be one to be specifically prepared for repairing.
Recently, a special attention has been paid to a middle density fiber board (MDF), which is said to have a property similar to a plywood. As the material of such a board is composed of fine woody fibers, the final product to be obtained by using it may thereby have a better surface smoothness. Therefore, it is recommended to employ the raw material.
The hot-pressing method of forming the woody board of the present invention may be either a hot plate-pressing method or a hot roll-pressing method. As a heating means in the method, a hot plate or a hot roll may be applied to the materials to be laminated and molded under pressure, or a hot steam may also be applied thereto under pressure. If desired, the materials to be laminated and molded may previously be heated by blowing a hot steam thereto or by heating them in an oven, and the thus pre-heated materials may be pressed and integrated to obtain the intended woody board.
As the adhesive to be applied to the respective molding materials and laminates of the present invention, a hot-gluing adhesive is used since the molding materials and laminates are pressed under heat to give an integrated woody board. Any conventional adhesives well known in this technical field, such as phenolic resins and melamine resins, can be used for the purpose. Where thermosetting and water-proofing resins such as melamine resins are selectively used, the water-proofness of the molded board layers is advantageously improved.
The thickness of the molded layer of a woody material may well be increased or decreased in accordance with the object of the woody board to be prepared. For instance, where the object of the board is to have merely a smooth surface, the layer of the molded layer may be thin to have a thickness of from 1 to 2 mm after being shaped.
It is preferred that the molded layer of a woody material is put on the both surfaces of the substrate both in the same thickness, in view of the balance to be formed. In accordance with the present invention, however, since the thickness of the molded layer of a woody material may well be much similar than that of the substrate, it is possible to prepare a one side-molded woody board with no warp and it is also possible to prepare a both sides-molded woody board where the molded layer on the two surfaces each have a different thickness.
The woody material for the molded layer may be either in the form of an already cold-pressed sheet or an adhesive-applied but not cold-pressed sheet. In the latter case, the woody material is in the form of a compound of woody fibers as already blended with an adhesive. If desired, the woody material for a molded layer may also be in the form of a sheet obtained by pre-hot-pressing the woody fibers along with said adhesive. If desired a two-stage polymerizing resin may advantageously be used as an adhesive. Further, the respective woody material layers may be pre-shaped by a first hot-pressing and thereafter they are integrated by a second hot-pressing.
The layers of coniferous wood in the present invention are preferably a coniferous tree plywood or a coniferous tree LVL in view of the objects of the present invention. An adhesive may be coated to said layers to give a molded coniferous tree plywood or LVL. The resulting coniferous tree plywood or LVL layer is used as the woody substrate. The woody substrate may also be in the form of a sheet as prepared by hot-pressing the corresponding plywood or LVL piled strips, or in the form of a cold-pressed piled strips prior to hot-pressing, or in the form of an adhesive-applied but not cold-pressed layer of veneers or laminars.
Where a board only is formed of an MDF, the mechanical strength of the resulting MDF board is lowered so that the flexibility of the board is large, as mentioned above. Therefore, a satisfactory board, e.g., large-sized board, could not be formed of such an MDF. In addition, since an MDF board is often waved or warped, the thickness thereof is generally up to 3 mm. Because of these reasons, a thin and strong woody material could not be obtained by the molding of MDF layers. In accordance with the present invention, however, since the woody substrate is a coniferous tree veneer or coniferous tree LVL, with the aforesaid woody material layer formed on one or both surfaces of the woody substrate, the board layer may well have a thickness of 3 mm or less in order to obtain the intended woody board. As a result, the woody board of the present invention has a smooth surface and a high mechanical strength.
In addition, in accordance with the present invention, an extremely thin woody material molded layer may be formed on the surface(s) of the woody laminate substrate. Therefore, even though the coat may be formed on only one surface of the substrate to form a one surface-molded board, the resulting one surface-molded board is advantageously free from warping.
The present invention will be explained in more detail by way of the following examples, which, however, are not intended to restrict the scope of the present invention. Unless otherwise specifically indicated, "%" is % by weight in these examples.

EXAMPLE 1

A melamine resin adhesive was applied to five sheets of Douglas fir rotary veneer each having a thickness of 2.5 mm in the direction perpendicular to the fibrous direction of each sheet by a known method of forming a conventional plywood, and the thus adhesive coated sheets were cold-pressed to form a woody substrate. The veneers constituting the surfaces of the substrate had 25 knots, each having a diameter of approximately 35 mm in the area of 1850 mm x 980 mm.
On the other hand, as woody material, wood of Douglas fir rotary veneer was finely reduced to fibers, and the resulting wood fibers were blended with 12 % of a melamine resin adhesive by spraying to prepare a woody material mix for a MDF material. This was put in an iron plate in a thickness of 15 mm, and the previously cold-pressed plywood was put thereover. Further, woody material mix was put over the plywood in a thickness of 15 mm.
The thus piled-up woody layers were inserted into a hot pressing machine along with the iron plate, where they were hot pressed at a temperature of 130°C at a pressure of 12 kg/m² for 10 minutes. Accordingly, a flat and smooth 14.5 mm-thick woody board having a board layer of one mm thickness on both surfaces thereof was prepared.
A decorative veneer of Douglas fir having a thickness of 0.6 mm was stuck to one surface of the woody board to give a decorative plywood having an extremely flat and smoothly finished surface.

EXAMPLE 2

In accordance with the same process as in Example 1, except that the woody material layer was put on only one surface of the cold-pressed plywood substrate, a woody board having one smooth and flat surface was obtained by hot-pressing.
The woody board thus obtained warped with the smooth surface being convex in such a condition that the arrow height was 1.5 mm to the length of 1850 mm. However, the warp of such a degree has heretofore been said to cause no problem in practical use of the board, and the board stood the product standard test.

COMPARATIVE EXAMPLE 1

In accordance with the same process as in Example 1, except that the thickness of the rotary veneer of Douglas fir, which was 2.5 mm in Example 1, was varied to 1.7 mm, a laminate substrate was prepared. Both surfaces of the substrate were coated with an MDF having a thickness of 3 mm, in place of the woody material as used in Example 1. The thus piled-up woody layers were then hot-pressed in the same way as in Example 1 to obtained a woody material having the same thickness as that obtained in Example 1.
The thus prepared woody material had a low and insufficient mechanical strength relative to the thickness thereof and therefore it was not suitable to practical use. The mechanical strength values of the product are shown in Table 1 below.

COMPARATIVE EXAMPLE 2

The same process as in Comparative Example 1 was repeated, except that an MDF was coated on only one surface by hot-pressing. Though the woody material product obtained had a smooth surface, it warped with the MDF coated surface being convex in such a condition that the arrow height was 13 mm to the direction of the length of being 1850 mm.
The warp was too large so that the product was no more practical.

COMPARATIVE EXAMPLE 3

The same process as in Example 1 was repeated, except that the thickness of the rotary veneer of Douglas fir rotary veneer, which was 2.5 mm in Example 1, was varied to 2.9 mm and that the woody material was not used, but a coniferous tree plywood was only used. Accordingly, a decorative plywood having almost the same thickness as that of the product of Example 1 was prepared.
The decorative plywood thus prepared had many knots and cracks, and the outward appearance thereof did not stand the test.

The physical data of the products obtained in the above-mentioned examples and comparative examples are shown in Table 1 below.

	Bending Strength (kg/m²)	Bending Young's Modulus (x 10³ kg/m²)	Arrow Height of Warp (mm)	Outward Appearance
Example 1	555	5.15	0	O
Example 2	542	5.25	1.5	O
Comparative Example 1	342	3.11	0	O
Comparative Example 2	524	5.29	13	O
Comparative Example 3	683	10.04	0	X
Note: Arrow height of warp indicates the height of the warp of the center to the length of 1850 mm.

As is understood from the results and data obtained in the above-mentioned examples and comparative examples, substantially warp-free woody boards and decorated boards which have smooth and flat surfaces as their outward appearance and which have a sufficient mechanical strength are obtained by the method of the present invention, and the industrial advantage of the present invention is noticeable.
While the invention has been described in detail and with reference to specific embodiments thereof, it will be apparent to one skilled in the art that various changes and modifications can be made therein as may fall within the scope of the appended claims.

Claims

A wood board comprising an integrally molded layer of woody fibers provided on one surface or both surfaces of a woody substrate of plywood;

wherein said woody substrate consists of several sheets of tree veneer laminated to form said substrate; and in which

said molded layer of woody fibers is one that has been pressed and molded onto said substrate;
characterized in that

said substrate consists of five layers of a coniferous wood; the substrate has a thickness of 12.5 mm; and that the molded layer is in the form of a middle density fiber board having a thickness of 3 mm or less.
The woody board as claimed in Claim 1, wherein the thickness of the molded layer of woody fibers is 1 to 2 mm.
The woody board as claimed in Claim 1 and wherein said molded layer is provided on both surfaces of the woody substrate and pressed so as to integrally form a middle density fiber board having a thickness of 1 mm; and wherein each molded layer is laminated with a decorative veneer.
The woody board as claimed in Claim 1, wherein the woody substrate is a conifereous tree plywood or a coniferous laminated veneer lumber comprising five coniferous tree strips pressed together in a direction perpendicular to the fibrous direction of each strip.
The woody board as claimed in Claim 1, wherein the thickness of the veneer is 2.5 mm.
The woody board as claimed in Claim 1, wherein said molded layer of woody fibers is on one surface only of said woody substrate and the resulting woody board has an arrow height of warp of 1.5 mm at the center of a length of 1850 mm of said woody board.
A method of preparing a woody board in which a woody material mix obtained by blending an adhesive and woody fibers is molded on at least one surface of a woody substrate of a coniferous tree plywood;

the woody substrate being made from five sheets of a coniferous tree veneer that are laminated to form a substrate having a thickness of 12.5 mm;

and wherein the or each layer of woody material mix is pressed and molded onto said substrate to create a middle density fiber board having a thickness of 3 mm or less.
The method according to Claim 7 wherein the woody material mix is applied to the woody substrate by a hot-pressing method.
The method of Claim 8 wherein the hot-pressing method is a hot plate-pressing method.
The method of Claim 8 wherein the hot-pressing method is a hot roll-pressing method.