BACKGROUND OF THE INVENTION
1. Field of the Invention
[0001] The present invention relates to the manufacture of a molded wooden product by introducing
into a mold wood fibers to which a binder containing a synthetic resin or the like
has been added, and shaping this material by hot compression molding to obtain the
molded wooden product.
2. Description of the Related Art
[0002] In general, the manufacture of molded wooden products has been carried out by molding
wood fibers obtained by disintegrating wood chips by splitting or the like, and then
by utilizing the bindability of the wood fibers themselves during molding. The molded
wooden products are called hardboards, and the products themselves are uniform and
light and have few defects. These products have been widely utilized as interior construction
materials, furniture, interior substrates for cars, and television and stereo cabinets,
for example, since the surface thereof is smooth and has high heat-resistance, high
water-repellency and high moisture-resistance, and the strength is relatively high
for the thickness of the plate.
[0003] The molded wooden products are manufactured, for example, by a wet molding method
where wood chips are digested and disintegrated to form wood fibers, a synthetic resin
and a cellulose paper are then incorporated into the wood fibers, and this material
is dispersed in water and then filtered under pressure and compressed under vacuum
to form a mat. This mat or soft fiber plate is compression molded under heat. Alternatively,
a dry matting method can be used where a binder such as a synthetic resin is added
to bond the wood fibers which are then formed into a stack and pressed under heat
with a roll press to obtain a mat, and the mat is compression molded under heat into
the desired shape.
[0004] The manufacture of molded wooden products, by reference to an example of a conventional
dry matting method, is as follows. Wood chips are put in a digesting tank of a fiber-disintegrating
machine and are loosened therein by steam to soften the chips so that the fibers may
be disintegrated or split with ease. Next these chips are put into a disintegrating
disk and pulverized and disintegrated therein to obtain wood fibers. The wood fibers
are dried with hot air, and then these are fully blended with long fibers for the
purpose of improving their drawability. As an example, these long fibers can comprise
17% of hemp fibers and 7% of polypropylene fibers. Also added is 8% of a binder, such
as a phenol-type thermosetting resin, a thermoplastic resin or the like, and 1 to
5% of a water-repelling agent such as rosin, paraffin or the like. Next, the wood
fibers to which the binder and other additives have been added are stacked and compressed
under heat with a roll press to form an easily portable mat M1 having a thickness
of about 10 to 40 mm, as shown in Fig. 11.
[0005] Next, the mat M1 to be molded is cut to a size which is somewhat larger than the
size of the final article and set on the lower half 2 of the compression mold 1, as
shown in Fig. 12. The lower mold half 2 and the upper mold half 3 are heated to a
temperature in the range of 180°C to 220°C by the hot plates 4. The mold halves 2
and 3 are closed in alignment with each other by lowering the upper mold half 3. A
gas is generated during this step, and the gas is removed by opening the mold, and
thereafter, the upper and lower mold halves are again closed. These pre-compression
and gas-removal steps are repeated several times, and then the mat is finally compressed
by the upper mold half 3 and the lower mold half 2, as shown in Fig. 13. Afterwards,
the mold is opened, and the product is removed therefrom as the molded wooden product
M2. In Fig. 13, M2' represents excess material derived during molding.
[0006] The above-described conventional method for the manufacture of molded wooden products
has several problems. The dry matting method requires the step of forming the wood
fibers into a mat which can be easily handled and the step of cutting the mat into
a desired shape. These steps are required so that the mat can be applied to the compression
mold with ease. Thus, the method requires additional steps, making it unnecessarily
complex. In addition, a binder such as thermoplastic resin or the like is required
to form the wood fibers into mats. Further, when the mat is molded under compression,
the mat is apt to be drawn into the mold especially in the deep-drawn portion thereof,
and, therefore, the mat is required to be cut in a somewhat larger size than the size
of the final molded product. This is uneconomical because the resulting excess material
must be cut away and discarded after molding of the product. Thus, the yield of the
process is reduced, and the manufacturing cost is increased. In addition, the need
for a cutting step after molding the product creates an additional burden. In molding
wooden products to have a deeply-drawn portion, long fibers such as expensive hemp
fibers and a binder such as a thermoplastic resin are required to be incorporated
into the material which forms the mats, in addition to the woods fibers, in order
to improve the deep-drawability of the mats. When hemp fibers having no adhesiveness
are used, an extra amount of thermosetting resin or like binder is required. This
results in an increase in the manufacturing costs, making the product expensive.
[0007] In the case of the manufacture of molded products having a deeply-drawn portion,
when the amount of wood fibers contained in the mat is large, the mat is required
to be softened with steam and then pre-shaped into the shape of the article to be
obtained, in order to improve the deep-drawability of the mat. In this case, not only
an extra step is required but the edge of the mat which is stretched by the deep-drawing
is made thin. When the pre-shaped mat is molded under compression, the thinner edge
will have a low density, and the strength of the final molded wooden product is decreased,
especially at the edge thereof. This creates a problem for the manufacturer. In the
case where a molded wooden product in the shape of a large plate having a deep-drawn
portion is to be formed from a single mat, the mat when drawn into the deep-drawn
portion may be broken or folded in the portion near the deep-drawn portion. The density
of the folded portion increases, the folded portion becomes blistered, and a wooden
product having the desired shape is not obtained. In order to solve these problems,
patches made of the same material as that of the mat are applied to the mat in the
portion to be deep-drawn prior to molding. This makes the operation burdensome and
unduly complicated.
[0008] When the wet molding method is used, a large amount of water is required for the
mat-making step, and, therefore, a large-scale drainage system is necessary. Furthermore,
the manufacture of a wooden product having a deep-drawn portion from a mat formed
by the wet-molding method is as at least as difficult as the above-discussed dry matting
method, since the fibers become entangled in the formed mat. Thus, the wet-molding
method has the same types of problems as the dry matting method, e.g., the deep-drawn
portion and the peripheral portion of the final product are thinner or broken.
[0009] A method has been considered for the direct compression molding of wood fibers where
wood fibers are directly put in a mold of a desired shape and molded therein under
compression. When a molded product in the shape of a plate is manufactured by such
a molding method, almost all the above-mentioned problems can be solved. However,
in the molding of deep-drawn portions, special attention is required regarding the
molding procedure because, if the compression molding is carried out merely under
a conventional process, sufficient deep-drawability is not attained.
[0010] Under these circumstances, the present inventors have previously proposed a method
for the manufacture of molded wooden products in Japanese Patent Application No. 60-230483,
filed October 16, 1985, where wood fibers to be molded are formed in a predetermined
shape of low density and the shaped mass is put in a mold and compression molded under
heat. This proposal has solved many of the above-mentioned problems in the use of
mats. However, where the mass of material contains wood fibers which have not been
completely disentangled, once compression starts the wood fibers are found to be lacking
in fluidity within the mold. Accordingly, in the case of molding deep-drawn portions,
the edge of the deep-drawn portion is thinner and the molded product is of reduced
quality.
SUMMARY OF THE INVENTION
[0011] It is an object of the present invention to solve the above-mentioned problems, to
improve the yield of molded wooden products and the manufacture thereof, and to ensure
that the molding process has a deep-drawing capability. The present invention provides
a method for the manufacture of molded wooden products of an improved quality, and
which does not require a mat-forming step.
[0012] Additional objects and advantages of the invention will be set forth in the description
which follows, and in part will be obvious from the description, or may be learned
by practice of the invention. The objects and advantages of the invention may be realized
and obtained by means of the steps and combinations particularly pointed out in the
appended claims.
[0013] To achieve the objects and in accordance with the purpose of the invention, as embodied
and broadly described herein, the molding process of this invention relates to the
manufacture of a molded wooden product made of wood fiber and having a deep-drawn
portion, and comprises the steps of introducing wood fibers into a compression mold,
initially compressing the wood fibers other than those used to form the deep-drawn
portion to an extent that the compressed fibers are prevented from further movement,
and then compression molding under heat both the wood fibers which were initially
compressed and the wood fibers used to form the deep-drawn portion to produce the
molded wooden product.
[0014] Preferably, in the method of the present invention, wood fibers to which a binder
or the like has been added are placed directly into a mold, and either the part of
the mold to accomplish deep-drawing or the other part is first closed to initially
compress the associated fibers. Then all of the wood fibers in the mold are compression
molded under heat. Alternatively, wood fibers to which a binder containing a synthetic
resin or the like has been added are formed into a mass of a predetermined shape,
the resulting mass is put into a mold, and either the part of the mold where deep-drawing
occurs or the remaining part is first closed to initially compress the associated
fibers. Thereafter the whole mass is compression molded under heat.
[0015] The fibers to be used in the present invention are obtained, for example, by disintegrating
wood. The wood used is not specifically limited to a specific type and may be, for
example, an akamatsu (Japanese red pine), a sugi (Japanese cedar), a lauan, a Japanese
beech, etc. In addition, rice straws, flax husks, bagasse, etc. can also be used.
[0016] Conventional processes for the preparation of wood fibers by disintegration of wood
chips or the like can be employed by anyone skilled in the art, and can include, for
example, the method of digesting wood under pressure and mechanically disintegrating
the wood into fibers under the same pressure or under normal pressure.
[0017] The binder to be added to the wood fibers is preferably one that complements the
bonding properties of the wood fibers themselves and the amount added is not specifically
limited, provided the wood fibers are bound together to form a molded wooden product
having desired strength. Examples include a synthetic resin, including a thermoplastic
resin such as a croman resin or a thermosetting resin such as a phenol resin or an
urea resin, and preferably a water-soluble phenol resin. These resins may be used
singly or in the form of a mixture thereof. In addition to the binder, other additives
such as a water-repelling agent for improving water-resistance can be added to the
wood fibers.
[0018] In the manufacturing method of the present invention, the wood fibers are placed
directly into the shaping mold, without being formed into a mat. The manner of introduction
of the wood fibers directly into the mold is not limited to a specific technique.
For instance, the wood fibers to which a binder has been added can be introduced into
the mold along with a gas such as air or the like, with the fibers being introduced
at one side of the mold under pressure and vacuum being applied at the other side,
or by vacuum alone at one side or introduced under pressure alone. The wood fibers
can also be directly dropped into the mold and accumulated therein; or the wood fibers
can be formed in a pile on a support such as a net or the like and transported into
the mold, the wood fibers being kept on the support by vacuum.
[0019] In another embodiment of the method of the present invention, the wood fibers to
be shaped are formed into a predetermined mass and introduced into a mold. The method
for thus forming this mass and the method for the transportation of the mass into
a mold are not specifically limited to any particular technique. For instance, a laminating
container is provided with a metal net therein and the fibrous material is introduced
into the container under vacuum so that the material forms in a pile on the metal
net. Thereafter, the material piled on the net is carried on a holder under vacuum,
transported into a shaping mold, and, once the preferred positioning of the material
is determined, the vacuum in the holder is released to drop the fibrous material into
position in the mold.
[0020] For the compression molding of the fibrous material where either the part of the
mold used for deep-drawing or the remaining part is first closed and then all of the
fibrous material is molded under pressure, the mold is divided into several parts
in the direction that compression is to occur, e.g., in the vertical direction, into
a part used for deep-drawing, and the remaining part of the mold. The wood fibers
residing in either of these thus-divided parts are first closed, and thereafter, the
whole mass of fibers is molded under pressure. In this process, the operation of "closing"
means to firmly press the wood fibers to such an extent that the fibers cannot move.
[0021] Since a time interval is to occur between the compression of the portion of the fibrous
material to be deep-drawn and that of the remaining part which is not to be deep-drawn,
either the upper mold or the lower mold constituting the entire mold is divided into
the corresponding part used for deep-drawing and the other part or parts not used
for deep drawing. One of the thus divided parts is vertically movable relative to
the other part or parts. The movable part is actuated by a moving means such as a
spring which applies an appropriate force. The molding parameters in this case are
based upon and determined in accordance with the wood fibers used, the type of binder,
the size or shape of the article to be produced, and the desired strength of the final
product. For instance, compression molding can be carried out at a temperature of
150°C to 220°C, a molding pressure of 20 to 80 kg/cm², and a molding time of 20 seconds
to 5 minutes.
[0022] In the method for manufacturing molded wooden products of the present invention,
the wood fibers to which a binder has been added are compression molded, and, therefore,
the wood fibers are integrally bonded. In addition, since the wood fibers can be directly
introduced into the mold, for example, by an air-flow, without being formed into a
mat, the fibers are not entangled but are unconnected and dispersed at random. Therefore,
the wood fibers are fully disintegrated and entrained in the fluid, and only a small
amount of binder need be used.
[0023] In deep-draw molding, where the wood fibers in the portion to be deep-drawn are first
closed or compresssed in the mold, the wood fibers in this part of the mold are stably
fixed in the mold, as in the case of a pre-shaped material. Alternatively, where the
other part of the mold -- other than the part to accomplish deep-drawing -- is first
closed to compress the wood fibers therein, the excess wood fibers shift to the part
of the mold where deep-drawing is to occur, and the latter part is sufficiently filled
with wood fibers so that the subsequent deep-drawing step can be carried out without
the deep-drawn portion of the final product being cracked or thinly formed.
[0024] Accordingly, the method of the present invention is not dependent upon a step of
forming the wood fibers into a mat and a step of cutting the mat to a determined shape.
In addition, the present method does not require binder in the formation of the mat.
Further, long fibers such as hemp fibers for the improvement of deep-drawability as
well as thermosetting resins for binding such fibers and extra amounts of thermoplastic
resins are unnecessary. The additional steps of pre-shaping, of reinforcing the portion
to be deep-drawn by applying patch materials thereto, and of applying steam to the
wood fibers in the portion to be deep-drawn, are unnnecessary in the manufacture of
molded products in accordance with the present invention, and the resulting molded
products have satisfactory strength.
[0025] In accordance with the method of the present invention, deep-drawability is improved
and high-strength molded wooden products can easily be obtained, as noted above. In
addition, some steps typically required in conventional matting methods can be omitted
in the method of the present invention. Therefore, complexity and the cost of raw
materials can be reduced, and productivity can be improved.
[0026] In the method of the present invention, the fibrous material to be molded can be
formed into a mass having a predetermined shape and the resulting mass introduced
into a shaping mold, making the process of forming a mat from the wood fibers unnecessary.
Again, the yield of the products is improved and the manufacturing process is simplified.
Furthermore, compression occurs when the wood fibers are in an untangled state, and
therefore, the wood fibers in the peripheral portions of the article are prevented
from moving inside the mold during compression molding. The forming of the external
shape of the molded product results only from compression molding, and, thus, the
step of afterworking the article for improving the surface characteristics of the
final product can be omitted.
[0027] A time interval occurs between the compression step of the portion of the fibrous
material to be deep-drawn and that of the remaining portions not to be deep-drawn,
thereby ensuring that a sufficient amount of wood fibers reside at the edge of the
portion to be deep-drawn so that the deep-drawing capability is improved.
[0028] The accompanying drawings, which are incorporated in and constitute a part of the
specification, illustrate preferred embodiments of the invention and, together with
the general description given above and the detailed description of the preferred
embodiments given below, serve to explain the principles of the invention.
BRIEF DESCRIPTION OF THE DRAWINGS
[0029]
Fig. 1 shows a sectional view in elevation of a mold (in open position) which can
be used in compression molding wood fibers in accordance with a first embodiment of
the method of the present invention;
Fig. 2 shows a sectional view in elevation of the mold of Fig. 1 in initially compressed
and partially closed position;
Fig. 3 shows a sectional view in elevation of the mold of Fig. 1 in fully compressed
and closed position with the wood fibers under compression;
Fig. 4 shows a plan view of a side plate of the mold used in the first embodiment
of the method of the present invention;
Fig. 5 shows a sectional view in elevation of a mold which can be used in compression
molding of wood fibers in accordance with a second embodiment of the method of the
invention;
Fig. 6 shows a view of an apparatus suitable for feeding wood fibers in the first
embodiment of the method of the present invention;
Fig. 7 is a schematic view showing an apparatus for forming a mass of wood fibers;
Figs. 8 and 9 are schematic views showing an apparatus for transporting a mass of
fibrous material formed by the apparatus of Fig. 7 and an embodiment for the use therof;
Fig. 10 is a perspective view of a molded wooden product manufactured in accordance
with a first embodiment of the method of the present invention;
Fig. 11 shows a perspective view of a mat of wood fibers used in prior art processes;
Fig. 12 shows a sectional view in elevation of a prior art mold in which a mat of
the type shown in Fig. 11 has been placed; and
Fig. 13 shows a sectional view in elevation of the mold of Fig. 12 with the mat of
Fig. 11 under compression.
DESCRIPTION OF THE PREFERRED EMBODIMENT
[0030] Reference will now be made in detail to the present preferred embodiments of the
invention as illustrated in the accompanying drawings. The present invention will
be explained in the following examples in which the processes of the present invention
are adapted, by way of example, to the molding of a door trim substrate with an arm
rest, this product finding utility in the manufacture of automobiles.
EXAMPLE 1:
[0031] An example of the manufacture of wood fibers will be first explained. Chips comprising
small pieces of wood obtained by chipping wooden materials are digested and disintegrated
at 160°C to 180°C. The wetted wood fibers thus obtained are dried with hot air.
[0032] Next, the dried wood fibers are put into a blender and stirred while they are simultaneously
sprayed with 1 to 5% of paraffin as a water-repellent agent, 2 to 10% (by dry weight)
of phenol resin-aqueous solution (resin content, for example, 50%) as a binder, and
a mold lubricant or the like. During the stirring and spraying process, the fibers
are well blended while the water content in the wood fibers is appropriately regulated
to obtain binder-containing wood fibers.
[0033] The wood fibers to which the binder has been added are directly introduced into a
shaping mold, without being formed into a mat. This step is carried out as follows.
[0034] The above-mentioned wood fibers M3 to which the binder has been added are put in
a feeding container 21 of filling apparatus 20, as shown in Fig. 6. The filling apparatus
20 is composed of the feeding container 21 and a pressure container 22. The two containers
are linked with each other via the opening 23 located at the bottom part of the feeding
container 21 and the aligned opening 23' at the upper part of the pressure container
22. The aligned openings 23 and 23' are blocked by the masking plate 24 which can
be opened and shut by the action of cylinder 26. The masking plate 24 is reciprocated
by the action of cylinder 26 so that a hole in the masking plate can be brought into
and out of alignment with the openings 23 and 23'. When the masking plate 24 is opened,
i.e., its hole is brought into alignment with holes 23 and 23', the wood fibers M3
to which the binder and the like have been added fall down to the pressure container
22 through the openings 23 and 23'. A pair of rotatable brush wheels are provided
in the lower part of the feeding container 21 where the wood fibers M3 have been kept.
These brushes when rotated cause the top of the brushes to engage with each other
which tend to untangle any entangled fibers of the wood fibers M3 that are contacted.
[0035] The pressure container 22 is provided with a weighing plate 27 below the opening
23', and the wood fibers M3 which fall through this opening pile up on this weighing
plate 27. The weight of the wood fibers M3 on the weighing plate 27 is measured by
a load cell (not shown) connected to the weighing plate 27, and when the weight has
reached a predetermined value, the brush wheels are stopped and the masking plate
24 is shut, thereby terminating the feeding of the wood fibers M3 into the pressure
container 22.
[0036] With reference to Fig. 1, the mold 30 comprises an upper mold 31 and lower mold 32.
The mold faces are inclined at an angle such that the angle for compression of the
portion to be deep-drawn is not too large. The lower mold 32 comprises several parts
including the fixed lower mold part 32a, positioned in the center of the mob for the
portion of the fibrous material to be deep-drawn, and the movable lower mold parts
32b which are supported by the springs 48 and are adjacent to the fixed part 32a.
The mold parts 32b are designed to compress the fibrous material surrounding the portion
of the fibrous material to be deep-drawn. In the state where the upper mold 31 and
the lower mold 32 are open, the movable mold parts 32b positioned adjacent to the
deep-drawing part of the lower mold 32 are elevated by the springs 48 to a height
higher than the fixed lower mold part 32a, but the stopper plates 46 connected at
the bottom of the lower mold parts 32b act to limit the upward movement of these parts
by contact with the top of stoppers 47.
[0037] The upper mold 31 has a deep-drawing part in concave form. When opened, the shaping
mold 30 forms a defined cavity, where the distance across the mold at the deep-drawing
part is wider than the other parts of the mold. The periphery of the mold 30 is surrounded
by side plates 33 and 34 so that the wood fibers M3 once fed into the mold do not
escape out of the mold 30. The side plates 33 and 34, which face each other, are movable
along the side surfaces of the mold 30. One side plate 33 has a feeding port 35 (see
also Fig. 4) opening to a position corresponding to the opening in the side of the
opened mold 30, and the other side plate 34 has a net 36 to hold the wood fibers M3
within the opened mold 30.
[0038] The discharge opening 28 provided in the pressure container 22 (Fig. 6) is designed
to be aligned with the feeding port 35 of the side plate 33 of mold 30 (Fig. 1). As
air is introduced into the pressure container 22 from the opening opposite to opening
28, the wood fibers M3 accumulated on the weighing plate 27 in the pressure container
22 are transported into the mold 30 by the air. In this procedure, the air passes
through the net 36 of the outer plate 34, while the wood fibers M3 are contained by
the net 36 and thus fill the cavity of mold 30.
[0039] During this introduction of the fibers under pressure, negative or a vacuum is also
applied at the downstream side of the net 36. The wood fibers M3 introduced into the
mold 30 under such pressure and vacuum collect from the mold side of the net 36 inwardly
without entangling the fibers. In this step, air contained in the wood fibers M3 are
degassed by vacuum via the air-removal holes 42 provided in the upper mold 31 and
the lower mold 32, and the vacuum ducts 43, to aid in uniformly filling the mold with
the wood fibers M3. In the air-removal procedure, the vacuum in the air-removal holes
in the side of the lower flow (in upper mold 32) may be varied relative to that of
the holes in the side of the upper flow (in upper mold 31) as the filling of the wood
fibers M3 in the mold 30 progresses. The quantity of wood fibers M3 admitted into
the mold 30 may be determined on the basis of their weight, as mentioned above, or,
alternatively, it may be determined on the basis of the pressure imparted during the
introduction of the fibers into the mold while the density of the fibers as they fill
the mold is appropriately regulated or monitored.
[0040] The wood fibers M3 to which the binder and other additives have been added are now
ready to be compression molded. First, the side plate 33 arranged on the side surface
of mold 30 is moved to cover the mold opening with the use of the rack 37 and pinion
39 gearing. The rack 37 is provided below the side plate 33, while the pinion 39 is
rotated by the motor 38 fixed to the bracket 40, so that the opening in mold 30 is
covered by the part of the side plate 33 (Fig. 4) adjacent to the feeding port 35
thereof, as shown in Fig. 2. In the same manner, the side plate 34 containing net
36 is also moved by a side-plate sliding means (not shown), so that this opening in
mold 30 is covered by the part of the side plate 34 adjacent to the net 36, as also
shown in Fig. 2. Thus, the position of these side plates 33 and 34 are fixed with
respect to the position of the lower mold 32.
[0041] Next, the wood fibers M3 are molded into the desired shape under compression created
between the upper mold 31 and the lower mold 32, which have been heated to a temperature
in the range of 150°C to 220°C by the hot plates 41, by downward movement of upper
mold 31 as shown in Fig. 2. The molding surfaces of the parts 32b of the lower mold
32 around the deep-drawing part 45 are elevated due to the springs 48, and thus, the
wood fibers M3 are sandwiched between the descending upper mold 31 and the lower mold
parts 32b, and pressed together. The lower mold parts 32b are supported by the springs
48 and, thus, the force exerted by the springs 48 is imparted as pressure to the wood
fibers M3. However, the height of the springs 48 is reduced under pressure created
by upper mob 31, and the lower mold parts 32b descend as the upper mold 31 descends
further. The descent of the lower mold parts 32b stops when the stopper plates 46
provided below these mold parts reach the hot plate 41 at the bottom of the mold.
In this state, the wood fibers M3 are closed or compacted in the area around the deep-drawing
part 45, but because a high level of pressure has not yet been imparted, the fibers
are not yet formed into a molded product. Any excess of wood fibers resulting from
this step flow into the deep-drawing part of the mold so that it is completely filled.
[0042] The upper mold 31 is now lowered further so that the wood fibers M3 across the entire
mold 30 are molded into the desired shape by the pressure created by the the upper
mold 31 and the lower mold 32 and the applied heat, as shown in Fig. 3. During this
step, any gas generated is removed under vacuum by the gas-removal holes 42 via the
vacuum ducts 43 and the valve 44 at the position approximately 10 mm before the bottom
dead point of the upper mold 31. The molding parameters can include, for example,
a molding pressure of 20 to 80 kg/cm² and a molding time of 20 seconds to 5 minutes.
[0043] In this process as just described, the peripheral part of the mold 30 adjacent to
the deep-drawing part 45 is first partially closed to initially compress the wood
fibers in the non-deep-drawn region, thereby preventing further movement of these
fibers. Afterwards, the entire mass of fibers is compression molded under heat into
the desired shape. This deep-drawn molding process operates in a stable manner without
the formation of thin regions in the final product or the susceptibility of the product
to breakage or fracture during manufacture. In addition, that part of the product
other than the deep-drawn portion is shaped in the initial compressing stage of the
molding process, and, therefore, the manufacturing yield is improved by eliminating
the waste encountered in the use of the mats.
[0044] When the mold is opened, vacuum applied through the gas-removal holes 42 in the upper
mold 31 holds the molded wooden product M4 against the upper mold 31 and it is thus
lifted up therewith. After the valve 44 is closed and vacuum is released, the molded
wooden product M4 is removed. The product has the shape of a door trim substrate in
which the deep-drawn part 45 is an arm rest, as shown in Fig. 10. This product is
free from defects and has a thickness of 2.5 mm and a bending strength of 200 to 350
kg/cm² or higher.
[0045] Since the molding is carried out with the interior mold surfaces being inclined,
in the present example, the compression angle and the drawing angle in the deep-drawn
portion are small. Therefore, molding can be achieved without the deep-drawn portion
being broken, and further, the final product can easily be removed from the mold.
EXAMPLE 2:
[0046] In this second example of the invention, the wood chips are digested, disintegrated
and dried to obtain wood fibers, in the same manner as in Example 1. The wood fibers
are preferably blended with the same binder, water-repellant agent, mold lubricant
and the like as in Example 1. The wood fibers to which the binder and other additives
have been added are put into the compression mold 50 shown in Fig. 5 by use of the
same techniques used in describing Example 1.
[0047] The mold 50 comprises an upper mold 51 and a lower mold 52. The upper mold 51 is
divided into a separately movable upper mold part 51a for use in deep-drawing and
the adjacent or surrounding upper mold parts 51b. With the wood fibers inside the
mold 50, the side plates 33 and 34 are closed to enclose the mold 50 as described
in Example 1. Next, the deep-drawing upper mold part 51a is lowered by the action
of the rod 49 so that the wood fibers M3 of the portion to be deep-drawn 45 are firmly
pressed together in this closing step. Afterwards, the upper mold parts 51b are lowered,
and all of the fibers M3 in the mold 50 are molded into the desired shape under hot
compression molding by the upper mold 51 and the lower mold 52. The wood fibers in
the deep-drawn part 45 have been pressed together during the closing step and correspond
to a pre-shaped mass. Therefore, this portion of the final product is stably deep-drawn
without being broken or made made unduly thin. The molding parameters may be the same
as used in Example 1. The final product obtained has equally superior strength as
that obtained in Example 1. In the process of the present example, additional steps
such as pre-compression are unnecessary, and the same or an improved result can be
attained as if these steps had been taken.
[0048] One embodiment of the mass-forming apparatus for the preparation of the fibrous mass
W is shown in Fig. 7. The mass forming apparatus 60 is principally comprised of a
spraying container 61 which has an angled roof-like form made of iron plate or the
like and a laminating container 62 for laminating the fibrous mixture M comprising
wood fibers, binder and other additives. Container 62 is positioned below container
61. The spraying container 61 has an opening 63 in the top thereof, and a nozzle 64
is provided above opening 63 for spraying the fibrous mixture M fed through a pressure
duct (not shown) to the nozzle. Air containers 65 are provided on both sides of opening
63, with each having an orifice in the inside thereof (not shown) for directing a
jet of air against the spray. These jets are used for regulating the direction in
which the mixture is sprayed. Each of these containers 65 is constructed to receive
air fed through air-feeding ducts 66 as switched by switch valve 67.
[0049] A vacuum duct 68 for applying vacuum to the interior of the laminating container
62 is connected to the bottom side of laminating container 62. A form-imparting part
69, which, for example, comprises a metal net, punched metal or the like and which
functions to form the bottom surface of the mass into a predetermined shape, is provided
above the vacuum duct 68. The laminating container 62 has height sensors 70 on the
side wall above the form-imparting part 69 for detecting the levels and thus the amount
of the mixture M and to form the upper surface of the mass W into a desired shape.
[0050] The operation of the mass-forming apparatus 60 is as follows. The switch valve 67
is opened to feed air into one or both of the air containers 65 through the air-feeding
ducts 66, and provide air-flow from the spraying container 61 to the laminating Container
62. Thereafter, mixture M is released from the nozzle 64 and passes through the opening
63. The released mixture M descends from the opening 63 of the spraying container
61 along with the air, in a floating manner, into the laminating container 62 to form
a predetermined accumulation on the form-imparting part 69. In this step, the air
jets provided by container 65 are appropriately regulated by switching the switching
valve 67, or by shutting both the valve and the orifices, so that the direction of
the falling mixture M is controlled and the fibers fall on predetermined positions
of the form-imparting part 69 where they quickly accumulate to the desired thickness.
In this procedure, air in the mixture is drawn from the bottom of the laminating container
62 by the vacuum duct 68, and the lamination of the mixture M is accelerated.
[0051] As the lamination of the mixture M proceeds, certain of the height sensors 70 provided
on the side wall of the container 62 detect that levels of the mixture M have reached
predetermined heights. The switch valve 67 is appropriately controlled so that the
direction of the fall of the fibrous mixture is changed. Eventually, all the sensors
70 will detect that the desired levels of the mixture M have been attained. At this
stage, the feeding of the mixture M is stopped and, at the same time, the feeding
of the air from the air-feeding duct 66 is also stopped. The mass of material W having
a predetermined shape is thus obtained. The mass W, constituted as a lamination of
fibers, has an extremely low density, and, generally, its thickness is selected to
be 20 to 120 times that of the final molded product.
[0052] In order to transport the fibrous mass W to the mold, the above-described laminating
container 62 is released from the spraying container 61, and is aligned with a holder
71, for example, as shown in Fig. 8. The holder 71 has a configuration capable of
receiving the laminating container 62, and is provided on the inside with a form-imparting
part 72 comprising a metal net or the like and shaped to correspond to the thickened
part WI of the material mass W. The top of holder 71 above part 72 is connected with
a vacuum tube 73. When a vacuum is applied to the vacuum duct 73, the fibrous mass
W is elevated by virtue of having a light specific gravity, and closely adheres to
the form-imparting part 72 in the holder 71, and with the vacuum maintained, the holder
is also lifted up with the fibrous mass and can now be moved by a conveying means
(not shown), in the direction shown in Fig. 9, to a predetermined position within
a mold, e.g., mold 30 or mold 50 of the present invention, where the mass is dropped
into the inside of the mold, in contrast to the feeding means used in the mold of
Fig. 1, and thereafter the vacuum is released and the mass W is set in the mold.
[0053] Additional advantages and modifications will readily occur to those skilled in the
art. The invention in its broader aspects is, therefore, not limited to the specific
details, representative apparatus and illustrative examples shown and described. Accordingly,
departures may be made from such details without departing from the spirit or scope
of the applicant's general inventive concept, provided they come within the scope
of the appended claims and their equivalents.
1. A method of manufacturing a molded wooden product composed of wood fibers and having
a deep drawn portion, comprising the introduction of said wood fibers into a compression
mould (30), the precompression and final compression of said wood fibers, wherein
the portions (31, 51, 32, 52) of said compression mould (30) have a deep-drawn region
and a non deep-drawn region,
characterized in that
(1) in a first step a space for said wood fibers within said compression mould is
closed before compression starts;
(2) one of said portions (32, 51) comprises at least one part (32a, 51a) relating
to said deep-drawn region and one part (32b, 51b) relating to said non deep-drawn
region, which parts are movable relative to each other during compression, wherein
in a second step said wood fibers used to form said deep-drawn region or said mood
fibers used to form said non deep-drawn region are precompressed to an extent that
the compressed fibers are prevented from further movement;
(3) in a third step said wood fibers, which were precompressed in said second step,
as well as a rest of said wood fibers are compressed to produce the molded wooden
product.
2. A manufacturing method as claimed in claim 1, wherein the first step comprises a first
substep of adding a binder to the wood fibers to bind the wood fibers together during
the compression molding of the third step, said first substep occurring prior to the
introduction of the wood fibers into the mold.
3. A manufacturing method as claimed in claim 1, wherein said first step comprises placing
wood fibers directly into the interior of the mold so that the wood fibers accumulate
within the mold.
4. A manufacturing method as claimed in claim 1, wherein said first step comprises a
second substep of forming the wood fibers into an unmatted fibrous mass prior to introduction
of said wood fibers into the mold.
5. A manufacturing method as claimed in claim 1, wherein the mold comprises upper and
lower molds, one of said upper and lower molds being formed into relatively movable
plural parts corresponding to the deep-drawn portion of the molded wooden product
and the remaining portions of said molded wood product, respectively, and the second
step comprises moving at least one of said movable parts of said one mold toward the
other of said upper and lower molds to initially compress the wood fibers other than
those wood fibers used to form the deep-drawn portion.
6. The manufacturing method as claimed in claim 1, wherein the third step comprises:
a first substep of heating the mold to a temperature in the range of 150°C to 220°C;
and
a second substep of continuing performance of said third step of compression molding
for a time period between 20 seconds and 5 minutes.
7. A manufacturing method as claimed in claim 1, wherein the mold comprises upper and
lower molds, one of said upper and lower molds being formed into relatively movable
plural parts corresponding to the deep-drawn portion of the molded wooden product
and the remaining portions of said molded wood product, respectively, and the second
step comprises moving at least one of said movable parts of said one mold toward the
other of said upper and lower molds to initially compress the wood fibers used to
form the deep-drawn portion.
8. A manufacturing method as claimed in claim 1, wherein the third step comprises:
a first substep of heating the mold to a temperature in the range of 150°C to 220°C;
and
a second substep of continuing performance of said third step of compression molding
for a time period between 20 seconds and 5 minutes.
1. Un procédé de fabrication d'un produit de bois moulé composé de fibres de bois et
comportant une partie produite par emboutissage profond, comprenant l'introduction
desdites fibres de bois dans un moule à compression (30), la précompression et la
compression finale desdites fibres de bois, dans lequel les parties (31, 51, 32, 52)
dudit moule à compression (30) comprennent une zone d'emboutissage profond et une
zone sans emboutissage profond, caractérisé en ce que:
(1) dans une première étape, un espace prévu pour lesdites fibres de bois dans ledit
moule à compression est fermé avant le début de la compression;
(2) l'une desdites parties (32, 51) comprend au moins une partie (32a, 51a) correspondant
à ladite zone d'emboutissage profond et une partie (32b, 51b) correspondant à ladite
zone sans emboutissage profond, lesdites parties étant mobiles l'une par rapport à
l'autre pendant la compression, de manière que lors d'une seconde étape, lesdites
fibres de bois utilisées pour former ladite zone d'emboutissage profond ou lesdites
fibres de bois utilisées pour former ladite zone sans emboutissage profond soient
précomprimées au point d'empêcher tout déplacement supplémentaire des fibres comprimées;
(3) lors d'une troisième étape, lesdites fibres de bois qui ont été précomprimées
lors de ladite seconde étape, ainsi qu'un reste desdites fibres de bois, sont comprimées
de manière à produire le produit de bois moulé.
2. Un procédé de fabrication selon la revendication 1, dans lequel la première étape
comprend une première étape secondaire d'addition d'un liant aux fibres de bois pour
les lier ensemble pendant le moulage par compression de la troisième étape, ladite
première étape secondaire ayant lieu avant l'introduction des fibres de bois dans
le moule.
3. Un procédé de fabrication selon la revendication 1, dans lequel ladite première étape
comprend l'agencement des fibres de bois directement à l'intérieur du moule, de manière
que les fibres de bois s'accumulent dans le moule.
4. Un procédé de fabrication selon la revendication 1, dans lequel ladite première étape
comprend une seconde étape secondaire de formation des fibres de bois en une masse
de fibres qui ne constitue pas une nappe et ce avant l'introduction desdites fibres
de bois dans le moule.
5. Un procédé de fabrication selon la revendication 1, dans lequel le moule comprend
des moitiés supérieure et inférieure de moule, l'une desdites moitiés supérieure et
inférieure de moule étant réalisée en une pluralité de parties mobiles les unes par
rapport aux autres, correspondant à la partie produite par emboutissage profond du
produit de bois moulé et les parties restantes dudit produit de bois moulé, respectivement,
et la seconde étape comprenant le déplacement d'au moins l'une desdites parties mobiles
de l'un desdits moules vers l'autre desdites moitiés supérieure et inférieure de moule,
pour comprimer les fibres de bois autres que les fibres de bois utilisées pour former
la partie réalisée par emboutissage profond.
6. Le procédé de fabrication selon la revendication 1, dans lequel la troisième étape
comprend:
- une première sous-étape de chauffage du moule à une température dans la plage de
150°C à 220°C; et
- une seconde sous-étape de poursuite de l'exécution de ladite étape de moulage par
compression pendant une période de temps comprise entre 20 secondes et 5 minutes.
7. Un procédé de fabrication selon la revendication 1, dans lequel le moule comprend
des parties supérieure et inférieure de moule, l'une desdites parties supérieure et
inférieure de moule étant réalisée en une pluralité de parties pouvant être en déplacement
relatif les unes par rapport aux autres et correspondant à la partie réalisée par
emboutissage profond du produit de bois moulé et aux parties restantes dudit produit
de bois moulé, respectivement, et la seconde étape comprenant le déplacement d'au
moins l'une desdites parties mobiles de ladite partie de moule vers l'autre desdites
parties supérieure et inférieure de moule pour comprimer initialement les fibres de
bois utilisées pour former la partie produite par emboutissage profond.
8. Un procédé de fabrication selon la revendication 1, dans lequel la troisième étape
comprend:
- une première sous-étape de chauffage du moule à une température comprise dans la
gamme de 150°C à 220°C; et
- une seconde sous-étape de poursuite de l'exécution de ladite étape de moulage par
compression pendant un intervalle de temps compris entre 20 secondes et 5 minutes.
1. Ein Verfahren zur Herstellung eines geformten, aus Holzfasern bestehenden sowie ein
tiefgezogenes Teil aufweisenden Holzprodukts, das das Einbringen der besagten Holzfasern
in eine Preßform (30), die Vorkompression sowie die Endkompression der besagten Holzfasern
umfaßt, wobei die Hälften (31, 51, 32, 52) der genannten Preßform (30) einen Tiefziehbereich
und einen Nichttiefziehbereich besitzen,
dadurch gekennzeichnet, daß
(1) in einem ersten Schritt ein Raum für die besagten Holzfasern innerhalb der genannten
Preßform, bevor eine Kompression beginnt, geschlossen wird;
(2) eine der erwähnten Hälften (32, 51) wenigstens ein dem genannten Tiefziehbereich
zugeordnetes Teil (32a, 51a) sowie ein dem genannten Nichttiefziehbereich zugeordnetes
Teil (32b, 51b) umfaßt, welche Teile während einer Kompression mit Bezug zueinander
bewegbar sind, wobei in einem zweiten Schritt die besagten, zur Bildung des genannten
Tiefziehbereichs verwendeten Holzfasern oder die besagten, zur Bildung des genannten
Nichttiefziehbereichs verwendeten Holzfasern in einem Ausmaß vorkomprimiert werden,
daß die komprimierten Fasern an einer weiteren Bewegung gehindert sind;
(3) in einem dritten Schritt die besagten Holzfasern, die in dem erwähnten zweiten
Schritt vorkomprimiert wurden, wie auch der Rest der besagten Holzfasern komprimiert
werden, um das geformte Holzprodukt zu erzeugen.
2. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß der erste Schritt
einen ersten untergeordneten Schritt des Zufügens eines Bindemittels zu den Holzfasern,
um die Holzfasern während des Preßformens im dritten Schritt aneinander zu haften,
umfaßt, wobei der erste untergeordnete Schritt vor dem Einbringen der Holzfasern in
die Form stattfindet.
3. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß der erwähnte
erste Schritt das Einbringen von Holzfasern unmittelbar in das Innere der Form umfaßt,
so daß sich die Holzfasern innerhalb der Form anhäufen.
4. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß der erwähnte
erste Schritt einen zweiten untergeordneten Schritt des Ausbildens der Holzfasern
zu einer nichtverflochtenen Fasermasse vor dem Einbringen der besagten Holzfasern
in die Form umfaßt.
5. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß die Form obere
und untere Formhälften umfaßt, eine der genannten oberen und unteren Formhälften aus
mehreren, relativ bewegbaren Teilen, die dem Tiefziehteildes geformten Holzprodukts
sowie den restlichen Teilen dieses geformten Holzprodukts jeweils entsprechen, gebildet
ist, und der zweite Schritt ein Bewegen der besagten bewegbaren Teile der genannten
einen Formhälfte zu der anderen der erwähnten oberen sowie unteren Formhälften hin,
um die Holzfasern außer denjenigen Holzfasern, die zur Ausbildung des tiefgezogenen
Teils verwendet werden, einleitend zu komprimieren, umfaßt.
6. Das Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß der dritte
Schritt umfaßt:
einen ersten untergeordneten Schritt des Erwärmens der Form auf eine Temperatur im
Bereich von 150 °C bis 220 °C; und
einen zweiten untergeordneten Schritt des Fortsetzens der Durchführung des erwähnten
dritten Schritts eines Preßformens für eine Zeitspanne zwischen 20 Sekunden und 5
Minuten.
7. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß die Form obere
und untere Formhälften umfaßt, eine der oberen und unteren Formhälften aus mehreren,
relativ bewegbaren Teilen, die dem Tiefziehteil des geformten Holzprodukts sowie den
restlichen Teilen dieses geformten Holzprodukts jeweils entsprechen, gebildet ist
und der zweite Schritt ein Bewegen von wenigstens einem der besagten bewegbaren Teile
der genannten einen Formhälfte zu der anderen der erwähnten oberen sowie unteren Formhälften
hin, um die zur Ausbildung des tiefgezogenen Teils verwendeten Holzfasern einleitend
zu komprimieren, umfaßt.
8. Ein Herstellungsverfahren nach Anspruch 1, dadurch gekennzeichnet, daß der dritte
Schritt umfaßt:
einen ersten untergeordneten Schritt des Erwärmens der Form auf eine Temperatur im
Bereich von 150 °C bis 220 °C; und
einen zweiten untergeordneten Schritt des Fortsetzens der Durchführung des erwähnten
dritten Schritts eines Preßformens für eine Zeitspanne zwischen 20 Sekunden und 5
Minuten.