[0001] The object of the present invention is a process for the preparation of a flocked
material starting from bicomponent fibres of a sea-island type, as well as a flocked
material obtained from this process. The flocked material that is obtainable by means
of this process can be used for various applications, for example to coat surfaces
and structures such as the interiors of motor vehicles, objects for interior decorating
(walls, sofas, armchairs, etc.), handbags, suitcases or other accessories, covers
or cases for weapons, musical instruments or electronic devices, or to make carpets
and/or rugs.
[0002] Electrostatic flocking is a particular process that makes it possible to obtain a
napped type of effect on various types of surfaces (fabrics, paper, plastic, metal,
wood, etc.). Flocking can be carried out on two-dimensional, rolled materials such
as paper or fabrics, as well as on three-dimensional objects (e.g. eyeglass frames,
clothes hangers, containers, interior components for automobiles, etc.).
[0003] In the flocking process, the synthetic fibres, which are normally already coloured,
are applied to a surface that has been previously treated with the application of
a specific glue. By means of an electrostatic field, the fibres penetrate the layer
of glue, orienting themselves perpendicularly to the surface to be napped.
[0004] In order for the fibres to orient themselves in the electrostatic field, they must
be cut uniformly, the length thereof normally being related to the size of fibre.
The smaller the diameter of the fibre, the shorter its length will be.
[0005] Prior to flocking, the fibres require pre-treatment for "activation", which is aimed
at predisposing the fibre to electrical conductivity. In general, solutions of metal
salts are used; as they coat the fibre surface, they facilitate the orientation of
the fibre in the electrostatic field.
[0006] Prior to or together with the activation step, a process of dyeing the flock can
also be carried out.
[0007] The flocking process thus requires the following steps:
- cutting the fibre
- optional dyeing
- activation of the fibres
- application of the glue on the backing layer
- laying the cut fibres in an electrostatic booth, which correctly orients the fibres
- drying and possible reticulation of the glue
- brushing with compressed air to remove excess fibres.
[0008] It is extremely difficult to obtain a flocked material realized with ultrafine fibres,
given that such fibres would have to be cut to a length that is too short, which is
not possible in an industrial process, and they would be extremely unstable and difficult
to work with in the activation process. Moreover, ultrafine fibres, which can be classified
as microfibres, would encounter more difficulty in penetrating the adhesive backing
layer, thereby jeopardizing the abrasion resistance of the flocked material.
[0009] However, the problem of using very short fibres for flocking surfaces has already
been addressed in the sector. In fact, flocked materials prepared starting from bicomponent
fibres of the sea-island type that are limited in length and utilizing an electrostatic
flocking process as described above are already known in the sector. Following the
flocking of the fibres on the substrate and after the glue has dried, the sea component
of the sea-island fibres is normally removed by means of the use of solvents such
as trichloroethylene or basic solutions.
[0010] For example, examples 15 and 16 in patent no.
GB1300268 discloses the preparation of a flocked material consisting of a base made of nylon
taffeta coated with a polyurethane adhesive, on which "islands-in-a-sea" type of composite
fibres are flocked by means of an electrostatic process; the island component of the
composite fibres is nylon 6,6 and the sea component is polystyrene. Prior to the electrostatic
process, the fibres are cut at a length of 3 mm and pre-treated with sodium silicate
and ammonium chloride. The flocked taffeta is dried and then immersed in a bath of
trichloroethylene at a temperature of 50-60°C to dissolve the sea component. Lastly,
it is washed with methanol and left to dry.
[0011] US patent no. 4574018 discloses a process for preparing a flocked material in which short sea-island bicomponent
fibres are flocked by means of an electrostatic procedure, over a base of various
type covered with an adhesive (e.g. a polyurethane adhesive). After reticulation of
the adhesive at high temperature, the sea component is removed partially by means
of immersion in trichloroethylene or in a 3% NaOH solution.
[0012] The issue of the workability of microfibres to create flocked materials has been
addressed in the prior art through the use of "sea-island" types of fibres. The fibres
are activated and laid on the backing layer prior to removal of the sea component.
[0013] However, the processes of the prior art have a major drawback concerning the sea
component removal step. In fact, the Applicant has found that when using solvents
similar to those known in the prior art, for example a basic solution of NaOH, the
sea component is completely removed, that is, even in the portion underlying the layer
of adhesive. In this regard, see Figure 1A, which shows the results of a removal step,
similar to those applied in the prior art, using solutions containing a solvent or
even basic solutions. The number 1 indicates the backing layer for the flocked fibres
and that can be of various types, whereas the number 2 indicates the layer of adhesive
(of various types) that is applied to the backing layer 1 prior to flocking. During
the electrostatic flocking procedure, the sea-island fibres (number 3 indicates the
island component and number 4 indicates the sea component), which have been previously
cut to a suitable length and pre-treated with inorganic salts, are oriented perpendicularly
with respect to the backing layer and a given portion of their length penetrates within
the adhesive layer.
[0014] Once the adhesive has been reticulated, if the flocked material is subjected to removal
of the sea component by means of immersion or treatment in an organic solvent (e.g.
trichloroethylene) or in a basic or acid solution, the problem shown in Figure 1B
is encountered: the sea component is removed completely, even in the portion inserted
in the adhesive layer. This is the cause of major problems with the structural resistance
and strength of the material, as substantially empty spaces are created between the
adhesive and the island component of the undissolved fibre. The fibres thus tend to
become detached from the substrate, as they are no longer "submersed" within the layer
of adhesive, resulting in "exfoliation" of the flocked material. See Example 7.0,
which was carried out by the Applicant, in which the removal step was performed by
immersing the flocked material in a bath containing 8% NaOH. The result is total removal
of the sea component, even in the part immersed in the adhesive, with the result that
the remaining fibre is no longer securely anchored to the backing layer and it can
be easily removed by abrasion, to the extent that in the next dyeing step in a jet
dyeing machine at the temperature of 120°C with disperse dyes, and resulting reduction,
the microfibre is completely removed from the adhesive layer.
[0015] This drawback concerning the step for dissolution of the sea component encountered
in the prior art processes has been resolved by the Applicant through the development
of a process according to the present invention.
[0016] The invention concerns a process for the preparation of the flocked material starting
from sea-island types of bicomponent fibres, comprising a step for selective removal
of the sea component carried out using a removal agent that has a viscosity ranging
between 300 mPa.s and 100.000 mPa.s, preferably between 400 and 64.000 mPa.s. The
removal agent is preferably in the form of a paste having a viscosity within the ranges
indicated above and that is spread on the fibres following flocking of the fibres
by means of an electrostatic process and drying of the adhesive layer.
[0017] Owing to its viscosity, the removal agent is unable to penetrate within the adhesive
layer where the sea-island fibres are partially immersed and therefore it is unable
to affect that part of the sea component that is immersed in the layer of adhesive.
Therefore, the removal of the sea component is a selective process and it makes it
possible to obtain a flocked material that offers good abrasion resistance and resistance
to fibre removal, unlike the flocked products known in the sector that are obtained
starting from sea-island fibres and have the drawback of offering poor resistance
to fibre removal by abrasion, as those same fibres are not securely anchored to the
layer of adhesive.
[0018] In a preferred embodiment of the process of the invention, a further measure can
be adopted to avoid corrosion of the sea component in the lower part of the fibres
and even more so in the part immersed in the adhesive layer; this measure consists
in protecting the above-mentioned portion of fibres by using a removable resin applied
by spreading, for example by air-spraying, prior to applying the removal agent. The
removable resin can have the same formulation as the removal agent, but without the
corrosive agent (which can be a caustic agent, acid or selective solvent). For example,
the removable resin can consist of a solution of polyvinyl alcohol or an aqueous solution
of a thickening agent in general, preferably compatible with the sea component with
which it comes into contact. The viscosity of the removable resin is greater than
that of the corrosive paste so as to prevent permeation between them.
[0019] Controlling the amount of removable resin deposited allows for finer modulation of
the fibre fraction to be dissolved.
[0020] Referring now to Figure 2, it can be noted that the selective removal step of the
invention makes it possible to obtain a flocked material in which the sea component
4 has been partially removed from the portion of fibre that is not immersed in the
adhesive layer. This constitutes a substantial structural difference between the flocked
material of the invention and the flocked material of the prior art, as can be seen
by comparing Figure 2 and Figure 1B, or Figures 5 and 6.
[0021] The invention thus also concerns a flocked material that can be obtained by means
of the process described hereinabove, in which the sea component of the sea-island
bicomponent fibre is partially removed from the portion of fibre that is not immersed
in the adhesive layer (Figure 2).
[0022] Keeping an undissolved portion of the sea component outside of the adhesive layer
also makes it possible to keep the fibre more localized at the flocking point and
this gives rise to a product with a more appealing appearance (the nap is perceived
as being more uniform).
[0023] The invention shall now be explained in detail below with reference also to the attached
figures, of which:
- Figure 1A shows the flocked material of the invention prior to removal of the sea
component;
- Figure 1B shows the flocked material with sea-island bicomponent fibres following
removal with a solvent solution and/or base solution of the prior art;
- Figure 2 shows the flocked material of the invention after selective removal of the
sea component by means of the removal agent of the invention;
- Figure 3 is a SEM (Scanning Electron Microscope) image of the flocked material of
the invention prior to removal of the sea component;
- Figure 4 is a SEM image of the flocked material following the selective superficial
removal of the sea component;
- Figure 5 is a detail from Figure 4 where the intact structure is evident at the base
of the emerging flocked fibers, whereas the sea component has been removed from the
upper part by selective dissolution;
- Figure 6 is a SEM image of the flocked material following non-selective removal of
the sea component by immersion in a bath of NaOH;
- Figures 7 and 8 are details from Figure 6 in which it is possible to see that the
microfibers with the sea component removed are not anchored to the layer of glue in
some points; the effect is particularly evident on the surface (Figure 8), where craters
can be seen on the layer of glue, left by the fibers that have lost their adhesion
following dissolution of the sea component.
[0024] The present invention concerns a process for the preparation of a flocked material
starting from sea-island bicomponent fibres, comprising the steps of:
- spinning a bicomponent fibre of the "island-in-the-sea" type;
- cutting the fibre to a length ranging between 0.1 mm and 3 mm, preferably between
0.3 and 1.25 mm;
- optionally, dyeing fibres with colouring agents, preferably with disperse dyes;
- activating the fibre by application of an aqueous solution of inorganic salts;
- applying an adhesive agent onto a backing layer made of fabric or non-woven fabric;
- laying the cut fibre on the backing layer coded with the adhesive agent by means of
electrostatic deposition, which correctly orients the fibres;
- drying and possibly reticulating the adhesive agent;
- optionally, removing excess fibres;
- optionally, applying a layer of removable resin at the base of the fibres to protect
the base of the flocked fibres;
- selectively and partially removing the sea component of the fibres by applying a removal
agent that has a viscosity ranging between 300 mPa.s and 100.000 mPa.s, preferably
between 400 and 64.000 mPa.s;
- optionally, proceeding with dyeing the flocked material.
[0025] The viscosity of the removal agent and of every other fluid has been measured as
reported in Example 8.0 unless specified otherwise.
[0026] The spinning of the sea-island bicomponent fibres can be carried out according to
prior-art techniques, which comprise the feeding of two pure polymers or two mixtures
of polymers to a spinneret so that one of the two polymeric components ("sea") completely
surrounds the other component constituted by various polymeric filaments (preferably
16 microfilaments of circular shape and equal diameter) that form the various "islands".
In this regard, the island component can be chosen from among: modified polyesters,
cationic polyesters, nylon or other types of polyamides (PA), polyethylene (PE), polypropylene
(PP), polytrimethylene terephthalate (PTT), polybutylene terephthalate (PBT) and polyethylene
terephthalate (PET), the latter being particularly preferred.
[0027] The island component can be solution-dyed, that is, dyed prior to spinning with the
aid of specific colouring agents or pigments added during the spinning process.
[0028] The sea component can be chosen from among: nylon 6,6, co-polyester (called co-PES
or TLAS) with a different content of monomer soluble in alkali, modified polyolefins
with insertion of polar monomers in the chain, the polar monomers preferably being
selected from among vinyl alcohol, vinyl acetate or maleic anhydride (called co-PS).
Depending upon the content of monomer soluble in alkali, the co-PES and co-PS can
be easily removed by adding a solution of alkali (low monomer content) or also in
hot water (high monomer content).
[0029] Both the sea and island components can be used in a mixture with added components
selected from among inorganic pigments for the island component, and incompatible
polymers for the sea component. Among the added inorganic pigments for the island
component, carbon black is particularly preferred. It makes it possible to achieve
a coloured "flock" in shades of colour ranging from grey to black, with a colouring
that proves to be particularly resistant to UV degradation, even by adding only small
amounts of the colouring agent.
[0030] Among the added incompatible components for the sea component, polyvinyl alcohol
for the co-PES and polyethylene glycols with average molecular weights between 10,000
and 20,000 g/mol for the co-PS, are particularly preferred.
[0031] In a particularly preferred embodiment, the fibre used in the invention is made up
of an island component made of PET and a sea component made of PA 6,6 or co-PES.
[0032] The ratio of the island component to the sea component in the bicomponent fibre is
such as to enable spinning of the two components by means of a spinneret rapidly and
efficiently. Said island/sea ratio is preferably within the range of 20/80 to 80/20,
more preferably within the range of 50/50 to 80/20. Seen in section, the fibre exhibits
a number of island components ranging from 8 to 96, preferably 8 to 40.
[0033] Following the spinning step, the bicomponent fibre thus obtained is subjected to
a drawing process so as to reduce the titre thereof from a range of 6.5 to 19.4 dtex,
preferably within the range of 9.2 to 17 dtex, to a titre ranging between 3 and 5
dtex. Drawing is carried out preferably with drawing ratios generally varying in the
range of 4-1, preferably in the range of 3-1, more preferably in the range of 2.5-1.
[0034] Following the drawing step, the "tow" thus obtained is collected in bins and undergoes
cutting of the continuous fibre to a length ranging between 0.1 mm and 3.0 mm. The
length of the fibre preferably ranges between 0.3 and 1.25 mm.
[0035] The cut fibre is subjected to an activation step preferably by means of immersion
in a bath of aqueous solution comprising inorganic salts, for example aluminium sulphate
and/or calcium chloride. Fibre that has been cut and activated is defined as "flock".
The length/diameter ratio in the flock must be within the range of 10:1 and 100:1,
preferably between 20:1 and 50:1.
[0036] This activation step makes the cut fibre more sensitive to the electrostatic field
applied during the electrostatic deposition step and thus enables a more precise orientation
of the fibres in a direction perpendicular to the substrate and to the adhesive layer.
[0037] Preferably, the flock is left to dry and after drying it has an inorganic salt content
within the range of 0.5% and 2% of the initial weight.
[0038] The backing layer on which a layer of adhesive agent is applied can be an orthogonal
fabric or a knit fabric, or a non-woven fabric such as a spun-bonded non-woven nylon
or polypropylene fabric, or a non-woven elastomeric composite fabric (hereinafter
identified as "EVN base"), for example polyester microfiber in a polyurethane matrix.
The backing layers indicated above can be utilized as is or they can undergo a surface
coating treatment to eliminate the porosity thereof, which would alter the thickness
of the applied adhesive agent on the surface; the surface coating treatment can also
facilitate fixing of the adhesive agent to the surface of the backing layer. Alternatively,
the backing layer can be a film made of a polyolefin, such as polypropylene pre-treated
with plasma to make the surface hydrophilic and thus easily wettable with the adhesive
agent, or it can be paper.
[0039] The backing layer has a unit weight ranging between 40 g/m
2 and 500 g/m
2, preferably between 80 g/m
2 and 350 g/m
2, and a thickness ranging between 0.10 mm and 2.0 mm, preferably between 0.20 mm and
1.10 mm.
[0040] The adhesive agent placed on the backing layer is preferably chosen from among: a
polyurethane adhesive (in a solvent or water), a water-based acrylic adhesive, and
a silicone glue; silicone glues and polyurethane adhesives are particularly preferred.
[0041] A pigment - and/or additives capable of facilitating adhesion with the bicomponent
fibre - can be added to the adhesive agent for the purpose of giving the final flocked
material specific shades of colour, preferably a conductive pigment capable of facilitating
the subsequent flocking process (making the backing layer conductive makes it possible
to neutralize the charges transported from the flock and thus keep the electrostatic
field applied constant). These additives, which are also called adhesion promoters,
are molecules possessing functional groups compatible with the adhesive agent (or
that react with the functional groups of the latter) and functional groups compatible
with the sea component (or that react with the functional groups of the latter) of
the bicomponent fibre that is made to penetrate into the glue. The layer of adhesive
agent can be applied by coating the entire surface of the backing layer (full application)
or only part of it (patterned application), for a thickness within the range of 0.05
mm to 0.50 mm, preferably 0.10 mm to 0.35 mm. In the case of patterned application,
the flock is stably deposited only in areas with the adhesive agent, thus realizing
patterns on the surface of the backing layer.
[0042] The electrostatic flocking of the flock on the adhesive agent layer preferably takes
place in an environment with a controlled and constant level of humidity ranging between
60% and 90%, preferably between 70% and 80%. The electrostatic field applied is preferably
within the range of 20 to 50 kV, preferably 20 to 40 kV.
[0043] The amount of flock deposited ranges between 50 and 250 g/cm
2, preferably between 140 and 190 g/cm
2, relative to the area in which the adhesive agent is present in the case of patterned
deposition.
[0044] The titre of the sea-island fibre ranges from 1.5 dtex to 10 dtex, preferably within
the range of 3.0 dtex to 7 dtex.
[0045] The deposition rate is between 2 and 7 m/min, preferably between 2 and 4 m/min.
[0046] The flock fibres penetrate within the adhesive layer to a depth ranging from 40 microns
to the entire thickness of the layer of adhesive agent, depending upon the adhesive
agent used, its viscosity and the applied electrical field.
[0047] Upon completion of deposition, the material is placed in an oven to harden and fix
the adhesive agent, for a period of time ranging from 2 to 10 minutes, preferably
3 to 5 minutes. The oven temperature is preferably in the range of 110°C and 200°C,
preferably 120 to 190°C.
[0048] Selective removal of the sea component takes place by applying a removal agent on
the flocked fibres, preferably in the form of a paste and having the viscosity indicated
hereinabove. The removal agent comprises a base, for example NaOH, or an acid, for
example formic acid, preferably mixed with a polysaccharide, preferably a polysaccharide
such as xanthan. Alternatively, the removal agent can also comprise a selective solvent
for the sea component. Examples of solvents suitable for dissolving a co-PS-based
sea component consist of halogenated solvents such as trichloroethylene, perchloroethylene,
chloroform, hydrocarbon solvents such as tuolene, xylene, ethylbenzene, cyclohexane,
and other polar solvents such as N,N-dimethylformamide, acetone, dioxane, tetrahydrofuran,
methyl ethyl ketone, acetonitrile, dimethy sulphoxide, methanol and ethanol.
[0049] The base or acid concentration may range between 1.5% and 20% by weight, preferably
between 4% and 18% by weight. The polysaccharide, and particularly the xanthan, is
preferably contained in the paste in an amount ranging from 0.5% to 7% by weight.
[0050] The removal agent is applied on the flocked fibres in an amount ranging between 80
and 150 g/m
2.
[0051] In a preferred embodiment of the invention, prior to applying the removal agent,
a removable resin can be applied by coating, as a further measure to avoid corrosion
of the sea component in the lower part of the fibres and even more so in the part
immersed in the adhesive layer. The removable resin can have the same formulation
as the removal agent, but without the corrosive agent (which can be a caustic agent,
acid or a selective solvent). For example, the removable resin can consist of a solution
of polyvinyl alcohol or an aqueous solution of a thickening agent in general, preferably
compatible with the sea component with which it comes into contact. The viscosity
of the removable resin is preferably greater than that of the removal agent so as
to prevent permeation between them. The viscosity of the removable resin preferably
ranges between 1.000 mPa.s and 150.000 mPa.s.
[0052] Controlling the amount of removable resin deposited allows for finer modulation of
the flock fraction to be dissolved.
[0053] Following application of the removal agent, the material can be treated with a saturated
vapour current, with radio frequencies, with microwaves or thermally treated with
hot air, so as to facilitate dissolution of the sea component. Following this optional
treatment, which can last 5 to 15 minutes (at a temperature of 70-100°C in the case
of thermal treatment), the removal agent and any removable resin can be removed by
washing with water. In this manner, selective and partial removal of the sea component
is brought about: only the portion of the sea component that is not immersed in the
layer of adhesive agent is removed, while the part immersed in the adhesive layer
remains and allows for maintaining secure anchoring of the flock fibers to the substrate
(see Figures 3-5, which show the absence of empty spaces between the island fibres
and the adhesive layer). According to a variant of the procedure, following application
of the removal agent, the material treated with a saturated vapour current, radio
frequencies or microwaves is further treated with hot air in an oven for the purpose
of creating a protective barrier on the surface of the removal agent before washing
with water.
[0054] In this manner it is possible to roll up the flocked material, for example in order
to transport it safely to the washing line, without jeopardizing the quality of the
final flocked material.
[0055] The fraction of fibre that has undergone removal of the sea component reveals the
microfibres constituting the island component, each having a titre in the range of
0.04 dtex to 0.30 dtex. In this manner, the flocked material becomes more resistant
to possible abrasions which could cause removal of the fibres and the microfibre proves
to be more localized at the flocking point based on the fraction of corroded fibre,
thus giving rise to a product with a more appealing appearance (the nap is perceived
as being more uniform). Moreover, the flocked material can also be dyed in a jet dyeing
machine and the excess dye then removed without risking a loss of flocked fibre. Alternatively,
to produce a flocked material without a mottled effect (flat appearance), it can be
dyed in a machine for garment dyeing or more generally for "open-width dyeing", which
permits pressurized dyeing of particularly delicate materials without subjecting them
to significant mechanical stress (the material remains spread open for its entire
width without forming lengthwise or crosswise folds).
[0056] Therefore, the flocked material that is obtained using the process of the invention
differs from the materials known in the
prior art in that it does not exhibit empty spaces between the fibres and the layer of adhesive,
which could contribute to the poor resistance of the prior art materials in the subsequent
dyeing steps and poor resistance to abrasion in general. The flocked material of the
invention presents itself as a finer material compared to those of the prior art and
offering greater durability over time.
[0057] Therefore, an object of the invention is a flocked material obtainable using the
process of the invention.
[0058] The flocked material of the invention comprises:
- a backing layer, preferably made of fabric or non-woven fabric;
- an adhesive layer applied onto the backing layer;
- a fibrous layer comprising a plurality of sea-island fibres that are preferably oriented
in a direction perpendicular to the backing layer, partially immersed in the adhesive
layer and having the sea component still present in the portion of fibres immersed
within the adhesive layer. The sea component is instead totally or partially absent
in the section of fibres that emerges from the adhesive layer.
[0059] The adhesive layer is present on the entire surface of the backing layer or on a
portion thereof (patterned flocking).
[0060] The adhesive layer is of a thickness ranging between 0.05 mm and 0.50 mm, preferably
between 0.10 mm and 0.35 mm.
[0061] The plurality of sea-island fibres are included within the adhesive layer for a depth
that ranges from 40 microns to the entire thickness of the adhesive layer.
[0062] The island component of the sea-island fibres has a titre in the range of 0.04 to
0.30 dtex.
[0063] The flocked material of the invention can be used in the field of automobiles, furnishings
and consumer electronics, replacing all parts currently coated with fabrics, non-wovens
or leathers.
[0064] In particular, the flocked material of the invention can be used for various applications,
for example to coat surfaces and structures such as interiors of motor vehicles, objects
for interior decorating (walls, sofas, armchairs, etc.), handbags, suitcases or other
accessories, covers or cases for weapons, musical instruments or electronic devices,
or to make carpets and/or rugs.
Examples of embodiments and comparative examples
Example 0.1 White flock with PET/TLAS bicomponent fibre - 1.0 mm
[0065] An "island-in-the-sea" type of bicomponent fibre flock is realized, in which the
island component is realized in PET and the sea component is realized in TLAS (co-polyester
soluble in alkali). The ratio of the island component to the sea component in the
fibre is 57:43.
[0066] The section of the fibre reveals 16 PET microfilaments of circular shape and equal
diameter.
[0067] The flock is obtained by means of the subsequent procedures of drawing, collecting
the tow in bins and cutting the continuous sea-island fibre to the desired length.
[0068] The characteristics of the fibre and the flock are as follows:
- 1- drawing ratio 2.5/1
- 2- titre 4.3 dtex
- 3- length 1.0 mm
[0069] The flock thus defined undergoes activation by means of immersion in a bath of an
aqueous solution of aluminium sulphate; after drying, the content of aluminium sulphate
in the flock is equal to 1% of the initial weight.
[0070] The flock thus realized is called
Thread 1.
Example 0.1.1 Black flock with (PET+disperse dyes)/TLAS bicomponent fibre
[0071] The flock is realized with the same procedure used for
Thread 1, with the variant that prior to the activation process the flock is dyed with black
dye dispersed in water at a temperature of 120°C in accordance with the prior art.
[0072] Subsequent activation leaves 1% aluminium sulphate by weight on the flock. The flock
thus realized is called
Thread 2.
Example 0.2 Black flock with solution-dyed PET/TLAS bicomponent fibre - 0.3 mm
[0073] An "island-in-the-sea" type of bicomponent fibre flock is realized, in which the
island component is realized in PET with added Carbon Black in the amount of 7% and
the sea component is realized in TLAS (co-polyester soluble in alkali). The ratio
of the island component to the sea component in the fibre is 57:43.
[0074] The section of the fibre reveals 16 PET microfilaments of circular shape and equal
diameter.
[0075] The flock is obtained by means of the subsequent procedures of drawing, collecting
the tow in bins and cutting the continuous sea-island fibre to the desired length.
[0076] The characteristics of the fibre and the flock are as follows:
- 1- drawing ratio 2.5/1
- 2- titre 4.3 dtex
- 3- length 0.3 mm
[0077] The flock thus defined undergoes activation by means of immersion in a bath of an
aqueous solution of aluminium sulphate; after drying, the content of aluminium sulphate
in the flock is equal to 1% of the initial weight.
[0078] The flock thus realized is called
Thread 3.
Example 0.3 White flock with PET/PA6.6 bicomponent fibre - 0.5 mm
[0079] An "island-in-the-sea" type of bicomponent fibre flock is realized, in which the
island component is realized in PET and the sea component is realized in PA 6,6.The
ratio of the island component to the sea component in the fibre is 57:43.
[0080] The section of the fibre reveals 16 PET microfilaments of circular shape and equal
diameter.
[0081] The flock is obtained by means of the subsequent procedures of drawing, collecting
the tow in bins and cutting the continuous sea-island fibre to the desired length.
[0082] The characteristics of the fibre and the flock are as follows:
- 1- drawing ratio 3.0/1
- 2- titre 3.8 dtex
- 3- length 0.5 mm
[0083] The flock thus defined undergoes activation by means of immersion in a bath of an
aqueous solution of aluminium sulphate; after drying, the content of aluminium sulphate
in the flock is equal to 1% of the initial weight.
[0084] The flock thus realized is called
Thread 4.
Example 0.4 White flock with PET/HWS bicomponent fibre - 1.0mm
[0085] An "island-in-the-sea" type of bicomponent fibre flock is realized, in which the
island component is realized in PET and the sea component is realized in HWS polyester.
The ratio of the island component to the sea component in the fibre is 57:43.
[0086] The section of the fibre reveals 16 PET microfilaments of circular shape and equal
diameter.
[0087] The flock is obtained by means of the subsequent procedures of drawing, collecting
the tow in bins and cutting the continuous sea-island fibre to the desired length.
[0088] The characteristics of the fibre and the flock are as follows:
- 1- drawing ratio 2.5/1
- 2- titre 4.3 dtex
- 3- length 1.0 mm
[0089] The flock thus defined undergoes activation by means of immersion in a bath of an
aqueous solution of aluminium sulphate, in the presence of 0.5% calcium chloride;
after drying, the aluminium flock undergoes a 1% increase in weight.
[0090] The flock thus realized is called
Thread 5.
Example 0.5 White flock with PET/TLAS bicomponent fibre -1.0 mm type A
[0091] An "island-in-the-sea" type of bicomponent fibre flock is realized and it is similar
to the one reported in Example 0.1 with the exception that the bicomponent fibre utilized
for realizing the flock has the following characteristics:
- 1- overall drawing ratio 3.5 /1
- 2- titre 3.1 dtex
- 3- length 0.5 mm
- 4- ratio of the island component to the sea component equal to 55:45
- 5- Section of the fibre containing 36 PET microfilaments of circular shape and equal
diameter.
[0092] The flock thus obtained undergoes activation by means of immersion in a bath of an
aqueous solution of aluminium sulphate, in the presence of 0.5% calcium chloride;
after drying, the aluminium flock undergoes a 1% increase in weight.
[0093] The flock thus realized is called
Thread 6.
Example 1.0 EVN base - silicone glue - 1.0 mm
[0094] A layer of bicomponent ALAPATEC 30340 adhesive (100% silicone glue supplied by CHT)
having a thickness of 0.2 mm and a viscosity of 50.000 mPa.s is applied onto a backing
layer realized in a composite material made of PET microfibre with 30% of a polyurethane
matrix and having a thickness of 1.10 mm.
[0095] Electrostatic and mechanical flocking follows so as to deposit the flock indicated
as
Thread 1; on average the flock penetrates into the layer of glue by 60 microns.
[0096] Flocking takes place in an environment with a controlled and constant level of humidity
at 65%, exposed to an electrostatic field of 30 kV so as to enable the deposition
of 144 g/ cm
2 of flock at a line rate of 3.0 m/min.
[0097] The intermediate product thus identified is placed in a convective oven to reticulate
for 4 minutes at 150°C and it is called
FK 01.0.
Example 1.1 EVN base - silicone glue - 1.0mm
[0098] An intermediate product similar to the one identified as
FK 01.0 (Example 1.0) is realized, using bicomponent TUBICOAT PROTECT LSR adhesive (100%
silicone glue, supplied by CHT). The glue contains a black pigment and has a viscosity
of 35.000 mPa.s, which is lower than that of ALPATEC 30340, to the extent that penetration
of the flock indicated as
Thread 1 equals the thickness of 0.2 mm of the glue and the flock is therefore in contact
with the surface of the backing layer.
[0099] The intermediate product is called
FK 01.1.
Example 1.2 EVN base - polyurethane glue - 1.0 mm
[0100] An intermediate product similar to the one identified as
FK 01.0 (Example 1.0) is realized, using an aromatic, bicomponent, polyester-based polyurethane
glue that can be reticulated by heating. The glue contains a black pigment and has
a viscosity of 30.000 mPa.s, which is lower than that of the preceding examples, to
the extent that penetration of the flock indicated as
Thread 1 equals the thickness of 0.2 mm of the glue and the flock is therefore in contact
with the surface of the backing layer.
[0101] The intermediate product thus identified is placed in a convective oven to reticulate
for 4 minutes at 150°C and it is called
FK 01.2.
Example 1.3 EVN base - polyurethane glue - 0.5 mm
[0102] An intermediate product similar to the one identified as
FK 01.0 (Example 1.0) is realized, using the flock indicated as
Thread 6, rather than Thread 1, and an aromatic, bicomponent, polyester-based polyurethane
glue that can be reticulated by heating. The glue has a viscosity of 29.000 mPa.s,
and penetration of the flock indicated as
Thread 6 equals the thickness of 0.2 mm of the glue and the flock is therefore in contact
with the surface of the backing layer.
[0103] The intermediate product thus identified is placed in a convective oven to reticulate
for 4 minutes at 150°C and it is called
FK 01.3.
Example 2.0 EVN base - silicone glue with adhesion promoter -1.0 mm
[0104] An intermediate product similar to the one identified as
FK 01.1 (Example 1.1) is realized, using bicomponent TUBICOAT PROTECT LSR adhesive (100%
silicone glue, supplied by CHT), which already contains within it a black pigment
and an adhesion promoter specific for TLAS. The glue has a viscosity of 35.000 mPa.s,
and penetration of the flock indicated as
Thread 3 equals the thickness of 0.2 mm of the glue (the flock is therefore in contact with
the surface of the backing layer).
[0105] The intermediate product is called
FK 02.0.
Example 3.0 fabric base - acrylic adhesive - 1.0 mm
[0106] A layer of TUBVINIL 401H adhesive of a thickness of 0.15 mm (water-based acrylic
base, supplied by CHT) is placed on a 100% PET cloth backing layer having a unit weight
of 82g/m
2 and electrostatic flocking is carried out with the flock indicated as
Thread 2. Flocking takes place in an environment with a controlled and constant level of humidity
at 65%, exposed to an electrostatic field of 30 kV so as to enable the deposition
of 165 g/cm
2 of flock at a line rate of 3.5 m/min.
[0107] Subsequently, the product is placed in a convection oven at 170°C for 3 minutes to
dry and fix the adhesive.
[0108] The flock penetrates into the adhesive to the point of coming into contact with the
underlying layer of fabric.
[0109] The intermediate product is called
FK 03.0.
Example 4.0 removable base - silicone glue - 1.0 mm
[0110] A layer of bicomponent TUBICOAT PROTECT LSR adhesive (100% silicone glue, supplied
by CHT) containing black pigment (see Example 1.1) and having a thickness of 0.4 mm
is placed on a strip of Teflon that has surface roughness.
[0111] This is followed by electrostatic flocking with the flock indicated as
Thread 1.
[0112] Flocking takes place in an environment with a controlled and constant level of humidity
at 65%, exposed to an electrostatic field of 40 kV so as to enable the deposition
of 210 g/cm
2 of flock at a line rate of 2.2 m/min.
[0113] Subsequently, the product is placed in a convection oven at 140°C for 6 minutes to
dry and fix the adhesive.
[0114] The flock penetrates into the adhesive to the point of coming into contact with the
underlying film.
[0115] The intermediate product is called
FK 04.0.
Example 4.1 PP base - polyurethane glue - 1.0 mm
[0116] A layer of aromatic, bicomponent, polyester-based polyurethane glue that can be reticulated
by heating, containing a black pigment and having a thickness of 0.4 mm is placed
over a film of PP having a thickness of 120 microns that has been pre-treated with
plasma to make the surface hydrophilic.
[0117] This is followed by electrostatic flocking with the flock indicated as
Thread 1.
[0118] Flocking takes place in an environment with a controlled and constant level of humidity
at 65%, exposed to an electrostatic field of 40 kV so as to enable the deposition
of 210 g/cm2 of flock at a line rate of 2.2 m/min.
[0119] Subsequently, the product is placed in a convection oven at 140°C for 3 minutes to
dry and fix the adhesive.
[0120] The flock penetrates into the adhesive to the point of coming into contact with the
underlying film.
[0121] The intermediate product is called
FK 04.1.
Example 5.0 spun-bonded base - silicone glue - PA 6,6 - 0.5 mm
[0122] A layer of bicomponent TUBICOAT PROTECT LSR adhesive (100% silicone glue, supplied
by CHT) having a thickness of 0.2 mm is placed over a spun-bonded PP fabric having
a unit weight of 90 g/m
2.
[0123] This is followed by electrostatic flocking with the flock indicated as
Thread 4.
[0124] Flocking takes place in an environment with a controlled and constant level of humidity
at 80%, exposed to an electrostatic field of 22 kV so as to enable the deposition
of 191 g/cm
2 of flock at a line rate of 2.5 m/min.
[0125] Subsequently, the product is placed in a convection oven at 150°C for 5 minutes to
dry and fix the adhesive.
[0126] The flock penetrates into the adhesive by 150 microns.
[0127] The intermediate product is called
FK 05.0.
Example 6.0 fabric base - PUD glue - HWS-1.0 mm
[0128] A layer of bicomponent TUBICOAT PROTECT LSR adhesive (100% silicone glue, supplied
by CHT) having a thickness of 0.2 mm is placed over a 100% PET cloth having a unit
weight of 82 g/m
2.
[0129] This is followed by electrostatic flocking with the flock indicated as
Thread 5.
[0130] Flocking takes place in an environment with a controlled and constant level of humidity
at 75%, exposed to an electrostatic field of 25 kV so as to enable the deposition
of 150 g/cm
2 of flock at a line rate of 3.0 m/min.
[0131] Subsequently, the product is placed in a convection oven at 150°C for 4 minutes to
dry and fix the adhesive.
[0132] The flock penetrates into the adhesive by 150 microns.
[0133] The intermediate product is called
FK 06.0.
Example 7.0 - Dissolution in a bath of NaOH + dyeing (Comparative example)
[0134] The intermediate products FK 01.0, FK 01.1, FK 01.2, FK 02.0, FK 03.0, FK 04.0 and
FK 04.1, containing TLAS as the sea component in the flock, were washed in a bath
containing 8% NaOH (w/w) at a temperature of 80°C for 15 minutes, and then washed
in cold water and placed in a convection oven to dry.
[0135] In intermediate products FK 01.0 and FK 03.0, it was evident that the flock was detached
from the layer of glue, leaving ample bare areas in which only glue and the substrate
were present.
[0136] In intermediate products FK 01.1, FK 01.2, FK 02.0, FK 04.0 and FK 0.041, the flock
remains on the surface of the product and the sea component is completely removed,
including the part submersed in the glue; therefore, the adhesion surface is limited
to the base of the microfibre only. For this reason, the microfibrous flocked product
tends to be easily removed by abrasion, to the extent that in the subsequent dyeing
step in a jet dyeing machine at the temperature of 120°C with disperse dyes, and resulting
reduction, the microfibre is completely removed from the glue.
Example 8.0 Dissolution with NaOH paste in air + dyeing
[0137] A preparation of thickened NaOH (removal agent) is dispensed using a doctor blade
at a rate of 100 g/m
2 on the flock side of the intermediate products FK 01.0, FK 01.1, FK 01.2, FK 02.0,
FK 03.0, FK 04.0 and FK 04.1 containing TLAS as the sea component of the flock.
[0138] The corrosive paste, 16% of which is constituted by NaOH and 0.5% of which by DENIMCOL
SPEC FTL (Xanthan polysaccharide supplied by CHT), has a pseudoplastic behaviour and
a viscosity of about 400 mPa.s under application conditions.
[0139] Viscosity was measured using a Brookfield DVIII rotational viscometer at 20°C, with
a Small Sample Adapter accessory and an SC4-28 spindle, at a speed of about 5 rpm,
corresponding to a shear rate of 5 s
-1.
[0140] The intermediate products coated with the corrosive paste were thermally treated
at 80°C for 10 minutes in an oven and then washed in cold water and placed in a convection
oven to dry.
[0141] SEM analyses showed that the sea component was affected only superficially (SEM image
of sample FK 01.1 in Figure 3).
Example 9.0 - Dissolution with NaOH paste in vapour
[0142] A preparation of thickened NaOH (removal agent) was dispensed using a doctor blade
at a rate of 100 g/m
2 on the flock side of the intermediate products FK 01.0, FK 01.1, FK 01.2, FK 01.3,
FK 02.0, FK 04.0 and FK 04.1 containing TLAS as the sea component of the flock.
[0143] The corrosive paste, 4% of which is constituted by NaOH and 2% of which by DENIMCOL
SPEC FTL (Xanthan polysaccharide supplied by CHT), has a pseudoplastic behaviour and
a viscosity of about 28.000 mPa.s under application conditions.
[0144] The intermediate products coated with the corrosive paste were treated with a saturated
vapour current at atmospheric pressure for 3 minutes and then washed in cold water
and placed in a convection oven to dry.
[0145] In intermediate products FK 01.1, FK 01.2, FK 01.3, FK 02.0, FK 04.0 and FK 04.1,
the sea component was completely removed in the non-submersed part of the flock in
contact with the corrosive paste revealing the microfibres, whereas the other part
was still had a microfibre nature and adhesion of the bundle to the backing layer
was also ensured (SEM image of the FK 01.1 sample, Figures 4 and 5).
[0146] Intermediate product FK 01.0 appeared with patches lacking flock on the surface owing
to insufficient penetration of the flock into the silicone glue.
[0147] Intermediate product FK 03.0 showed a loss of flock and glue on most of the surface.
Dyeing was then carried out in a jet dyeing machine with disperse dyes at 120°C and
subsequent reduction of excess dye only on intermediate products FK01.1, FK 01.2,
FK 01.3, FK 02.0, FK 04.0 and FK 04.1.
Example 9.1 - Dissolution with NaOH paste in vapour + open-width dyeing
[0148] The sea component of intermediate products FK 01.1, FK 01.2, FK 01.3, FK 02.0, FK
04.0 and FK 04.1 was removed as described in Example 9.0.The intermediate products
were then dyed by means of a dyeing machine for open-width dyeing, using disperse
dyes in water at 120°C and subsequent reduction of excess dye. In this manner, dyed
flocked materials were obtained, characterized by a more uniform and even appearance.
Example 10.0 Dual coating and vapour
[0149] A preparation of PVA in water with a viscosity of 54.000 mPa.s was applied onto the
intermediate products FK 01.1, FK 01.2, FK 02.0 and FK 04.0 by means of an air doctor
blade, with the aim of applying a layer of 30 g/m
2 of solution only at the base of the flocked fibres.
[0150] Subsequently, a preparation of thickened NaOH was dispensed by means of a cylinder
doctor blade at a rate of 100 g/m
2 on the flocked side of intermediate product FK 01.1.
[0151] The corrosive paste (removal agent), 4% of which is constituted by NaOH and 2% of
which by DENIMCOL SPEC FTL (Xanthan polysaccharide supplied by CHT), has a pseudoplastic
behaviour and a viscosity of about 28.000 mPa.s under application conditions.
[0152] The intermediate products FK 01.1, FK 01.2, FK 02.0 and FK 04.0 coated with the corrosive
paste were treated with a saturated vapour current at atmospheric pressure for 3 minutes
and then washed in cold water and placed in a convection oven to dry.
[0153] The sea component proved to be hydrolyzed only in the apical part of the flocked
fibres, that is, for about 1/5 of the emerged length.
Example 11.0 - Dissolution in water and RF - HWS
[0154] An aqueous solution of 1.5% DENIMCOL SPEC FTL (Xanthan polysaccharide supplied by
CHT) was dispensed by means of a doctor blade at the rate of 120 g/m
2 on the flock side of intermediate product FK 06.0.The viscosity of the solution under
application conditions was about 20.000 mPa.s.
[0155] The intermediate product was then subjected to radio frequencies with a parallel
field, with a difference in electric potential equal to 1.0 kV, and then washed in
cold water.
[0156] This was followed by immersion in a 10% calcium chloride solution for 8 minutes at
a temperature of 50°C for the purpose of making the residual sea component (HWS) insoluble
in the part of the flock that is submersed in the silicone glue, by washing with water
without hardening salts and by drying in a convection oven.
[0157] The intermediate product remains intact as it passes the next dyeing step for dyeing
with disperse dyes at 120°C in a jet dyeing machine and the reduction to eliminate
excess dye.
Comparative Example 12.0 - Dissolution in NaOH and MW (microwaves)
[0158] A preparation of thickened NaOH was dispensed by means of a doctor blade at the rate
of 100 g/m
2 on the flock side of intermediate product FK 01.1, then heated for 2 minutes in a
microwave oven with power equal to 5 KW, washed in cold soft water and dried in a
convection oven.
[0159] The corrosive paste (removal agent), 1.0% of which is constituted by NaOH and 2.0%
of which by DENIMCOL SPEC FTL (Xanthan polysaccharide supplied by CHT), has a pseudoplastic
behaviour and a viscosity of about 2.000 mPa.s under application conditions.
[0160] Following microwave treatment, the sea component in the part of the fibre emerging
from the glue proved to have been entirely removed, revealing the microfibre, while
it remained in the part anchored to the backing layer. Dyeing was then carried out
in a jet dyeing machine with disperse dyes at 120°C, as was subsequent reduction of
excess dye.
1. A process for the preparation of a flocked material starting from sea-island bicomponent
fibres, comprising the steps of:
• spinning a bicomponent fibre of the "island-in-the-sea" type;
• cutting the fibre to a length ranging between 0.1 mm and 3 mm, preferably between
0.3 and 1.25 mm;
• optionally, dyeing the fibres with colouring agents;
• activating the fibre by application of an aqueous solution comprising inorganic
salts;
• applying an adhesive agent onto a backing layer, preferably made of fabric or non-woven
fabric;
• laying the cut fibre on the backing layer coated with the adhesive agent by means
of electrostatic deposition, which correctly orients the fibres;
• drying and optionally reticulating the adhesive agent;
• optionally, removing excess fibres;
• optionally, applying a layer of a removable resin at the base of the fibres to protect
the fibre base;
• selectively and partially removing the sea component of the fibres by applying a
removal agent that has a viscosity ranging between 300 mPa.s and 100.000 mPa.s, preferably
between 400 and 64.000 mPa.s;
• optionally, proceeding with dyeing the flocked material.
2. The process according to claim 1, wherein said activation step comprises immersion
of the cut fibres in a bath of an aqueous solution comprising inorganic salts.
3. The process according to claim 2, wherein following the activation treatment, the
cut fibres are left to dry and after drying they have an inorganic salt content ranging
between 0.5% and 2% of the initial weight.
4. The process according to any one of the preceding claims, wherein the backing layer
on which the adhesive agent layer is applied consists of an orthogonal fabric or a
knit fabric, or a non-woven fabric, preferably a spun-bonded non-woven nylon or polypropylene
fabric, or non-woven elastomeric composite fabric, preferably polyester microfibre
in a polyurethane matrix, or a film made of polyolefin, preferably polypropylene,
or paper.
5. The process according to any one of the preceding claims, wherein the adhesive agent
that is placed on the backing layer is chosen from among: a polyurethane adhesive
in an aqueous or solvent dispersion, a water-based acrylic adhesive and a silicone
glue.
6. The process according to claim 8, wherein a pigment, preferably a conductive pigment
capable of facilitating the subsequent flocking process, and/or additives capable
of facilitating adhesion with the bicomponent fibre, are added to said adhesive agent.
7. The process according to any one of the preceding claims, wherein said electrostatic
flocking of the cut fibres on the adhesive agent layer takes place in an environment
with a controlled and constant level of humidity ranging between 60% and 90%, preferably
between 70% and 80%, with the application of an electrostatic field ranging between
20 and 50 kV, preferably between 20 and 40 kV.
8. The process according to claim 10, wherein the amount of cut fibres deposited on the
substrate ranges between 50 and 250 g/cm2, preferably between 140 and 190 g/cm2.
9. The process according to any one of the preceding claims, wherein said removal agent
comprises a base, preferably NaOH, or an acid, preferably formic acid, preferably
mixed with a polysaccharide.
10. The process according to any one of the preceding claims, wherein said removal agent
is applied on the flocked fibres in an amount ranging between 80 and 150 g/m2.
11. The process according to any one of the preceding claims, wherein following application
of the removal agent, the material is thermally treated with a saturated vapor current,
with radio frequencies, with microwaves or thermally with hot air.
12. The process according to any one of the preceding claims, wherein the viscosity of
said layer of removable resin is greater than that of said removal agent, preferably
within the range of 1,000 mPa.s and 150,000 mPa.s.
13. A flocked material comprising:
- a backing layer, preferably made of fabric or non-woven fabric;
- an adhesive layer applied onto the surface of the backing layer or a portion thereof;
- a fibrous layer comprising a plurality of sea-island fibres that are preferably
oriented in a direction perpendicular to the backing layer, partially immersed in
the adhesive layer and having the sea component still present in the portion of fibres
immersed within the adhesive layer and totally or partially absent in the section
of fibres that emerges from the adhesive layer.
14. The flocked material according to claim 16, wherein said adhesive layer is of a thickness
ranging between 0.05 mm and 0.50 mm, preferably between 0.10 mm and 0.35 mm.
15. The flocked material according to claim 16 or 17, wherein said plurality of sea-island
fibres are included within the adhesive layer for a depth that ranges from 40 microns
to the entire thickness of the adhesive layer.
16. The flocked material according to any one of claims 16 to 18, wherein the island component
of the sea-island fibres has a title in the range of 0.04 to 0.30 dtex.
17. A use of the flocked material according to any one of claims 16 to 19 in the field
of automobiles, furnishings and consumer electronics, replacing all parts currently
coated with fabrics, non-wovens or leathers, preferably to coat surfaces and structures
of the interiors of motor vehicles, objects for interior decorating (walls, sofas,
armchairs, etc.), handbags, suitcases or other accessories, covers or cases for weapons,
musical instruments or electronic devices, or to make carpets.
1. Verfahren zur Herstellung eines geflockten Materials, ausgehend von Insel-In-See-Zweikomponentenfasern,
umfassend die Schritte:
• Spinnen einer Zweikomponentenfaser vom Typ "Insel in See";
• Schneiden der Faser auf eine Länge zwischen 0,1 mm und 3 mm, vorzugsweise zwischen
0,3 und 1,25 mm;
• optional, Färben der Fasern mit Farbstoffen;
• Aktivieren der Faser durch Aufbringen einer wässrigen Lösung, die anorganische Salze
umfasst;
• Aufbringen eines Haftmittels auf eine Trägerschicht, vorzugsweise aus Stoff oder
Vliesstoff;
• Legen der geschnittenen Faser auf die mit dem Haftmittel beschichtete Trägerschicht
mittels elektrostatischer Abscheidung, die die Fasern korrekt ausrichtet;
• Trocknen und optional Vernetzen des Haftmittels;
• optional, Entfernen der überschüssigen Fasern;
• optional, Aufbringen einer Schicht eines entfernbaren Harzes auf der Basis von Fasern,
um die Faserbasis zu schützen;
• selektives und teilweises Entfernen der Seekomponente der Fasern durch Aufbringen
eines Entfernungsmittels, das eine Viskosität im Bereich zwischen 300 mPa.s und 100.000
mPa.s, vorzugsweise zwischen 400 und 64.000 mPa.s aufweist;
• optional, Vorgehen mit der Färbung des geflockten Materials.
2. Verfahren nach Anspruch 1, wobei der Aktivierungsschritt das Eintauchen der geschnittenen
Fasern in ein Bad einer wässrigen Lösung umfasst, die anorganische Salze umfasst.
3. Verfahren nach Anspruch 2, wobei nach der Aktivierungsbehandlung die geschnittenen
Fasern trocknen gelassen werden und nach dem Trocknen einen anorganischen Salzgehalt
im Bereich zwischen 0,5% und 2% des Anfangsgewichts aufweisen.
4. Verfahren nach einem der vorhergehenden Ansprüche, wobei die Trägerschicht, auf die
die Haftmittelschicht aufgebracht wird, aus einem orthogonalen Stoff oder einem Gewirk
oder einem Vliesstoff, vorzugsweise spunbonded Nylonvlies oder Polypropylen-Stoff
oder elastomeren Verbundvlies, vorzugsweise Polyestermikrofaser in einer Polyurethanmatrix,
oder eine Folie aus Polyolefin, vorzugsweise Polypropylen, oder Papier besteht.
5. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Haftmittel, das auf die
Trägerschicht platziert wird, ausgewählt wird aus: einem Polyurethanklebstoff in einer
wässrigen oder Lösungsmitteldispersion, einem wasserbasierten Acrylklebstoff und einem
Silikonkleber.
6. Verfahren nach Anspruch 8, wobei ein Pigment, vorzugsweise ein leitfähiges Pigment,
das den nachfolgenden Beflockungsprozess fördern kann, und/oder Additive, die die
Haftung mit der Zweikomponentenfaser fördern können, zum Haftmittel hinzugefügt werden.
7. Verfahren nach einem der vorhergehenden Ansprüche, wobei die elektrostatische Beflockung
der geschnittenen Fasern auf der Haftmittelschicht in einer Umgebung mit einem kontrollierten
und konstanten Feuchtigkeitsgrad zwischen 60% und 90%, vorzugsweise zwischen 70% und
80% mit der Anwendung eines elektrostatischen Feldes im Bereich zwischen 20 und 50
kV, vorzugsweise zwischen 20 und 40 kV erfolgt.
8. Verfahren nach Anspruch 10, wobei die Menge an auf dem Substrat abgeschiedenen geschnittenen
Fasern zwischen 50 und 250 g/cm2, vorzugsweise zwischen 140 und 190 g/cm2 liegt.
9. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Entfernungsmittel eine
Basis, vorzugsweise NaOH, oder eine Säure, vorzugsweise Ameisensäure, vorzugsweise
gemischt mit einem Polysaccharid, umfasst.
10. Verfahren nach einem der vorhergehenden Ansprüche, wobei das Entfernungsmittel auf
die geflockten Fasern in einer Menge zwischen 80 und 150 g / m2 appliziert wird.
11. Verfahren nach einem der vorhergehenden Ansprüche, wobei nach der Aufbringung des
Entfernungsmittels das Material mit einem gesättigten Dampfstrom, mit Radiofrequenzen,
mit Mikrowellen oder thermisch mit heißer Luft thermisch behandelt wird.
12. Verfahren nach einem der vorhergehenden Ansprüche, wobei die Viskosität der Schicht
aus entfernbarem Harz grösser ist als die des Entfernungsmittels, vorzugsweise im
Bereich von 1.000 mPa.s und 150.000 mPa.s ist.
13. Geflocktes Material, umfassend:
- eine Trägerschicht, vorzugsweise aus Stoff oder Vliesstoff;
- eine Klebeschicht, die auf die Oberfläche der Trägerschicht oder einen Teil davon
aufgebracht wird;
- eine Faserschicht, die eine Vielzahl an Insel-In-See-Fasern umfasst, die vorzugsweise
in einer Richtung senkrecht zur Trägerschicht orientiert sind, teilweise in die Klebeschicht
eingetaucht sind und wobei sie die Seekomponente, die im Abschnitt der Fasern noch
vorhanden ist, innerhalb der Klebeschicht eingetaucht aufweist, total oder teilweise
abwesend im Abschnitt von Fasern, der aus der Klebeschicht austritt.
14. Geflocktes Material nach Anspruch 16, wobei die Klebeschicht eine Dicke im Bereich
zwischen 0,05 mm und 0,50 mm, vorzugsweise zwischen 0,10 mm und 0,35 mm aufweist.
15. Geflocktes Material nach Anspruch 16 oder 17, wobei die Vielzahl von Insel-In-See-Fasern
innerhalb der Klebeschicht für eine Tiefe enthalten sind, die von 40 Mikrometer bis
zur gesamten Dicke der Klebeschicht reicht.
16. Geflocktes Material nach einem der Ansprüche 16 bis 18, wobei die Insel-Komponente
der Insel-In-See-Fasern einen Wert im Bereich von 0,04 bis 0,30 dtex aufweisen.
17. Verwendung des geflockten Materials nach einem der Ansprüche 16 bis 19 auf dem Gebiet
von Automobilen, Einrichtungsgegenständen und Unterhaltungselektronik, wobei alle
Teile, die gegenwärtig mit Stoffen, Vliesstoffen oder Ledern beschichtet sind, ersetzt
werden, vorzugsweise zum Beschichten von Oberflächen und Strukturen der Innenräume
von Kraftfahrzeugen, Gegenständen zur Inneneinrichtung (Wände, Sofas, Sessel usw.),
Handtaschen, Koffer oder sonstiges Zubehör, Abdeckungen oder Gehäuse für Waffen, Musikinstrumente
oder elektronische Geräte oder zur Herstellung von Teppichen.
1. Procédé destiné à la préparation d'un matériau floqué à partir de fibres bicomposées
mer-île, comprenant les étapes de :
• filer une fibre bicomposée de type « island-in-the-sea » (île en mer) ;
• couper la fibre selon une longueur comprise entre 0,1 et 3 mm, de préférence entre
0,3 et 1,25 mm ;
• éventuellement, colorer les fibres avec des colorants ;
• activer la fibre par l'application d'une solution aqueuse comprenant des sels inorganiques
;
• appliquer un agent adhésif sur une couche de support, de préférence en tissu ou
en tissu non tissé ;
• étendre la fibre coupée sur la couche de support revêtue de l'agent adhésif au moyen
d'une déposition électrostatique qui oriente correctement les fibres ;
• sécher et éventuellement réticuler l'agent adhésif ;
• éventuellement, retirer les fibres en excès ;
• éventuellement, appliquer une couche d'une résine amovible à la base des fibres
pour protéger la base de la fibre ;
• retirer de façon sélective et partielle le composant mer des fibres en appliquant
un agent détachant ayant une viscosité comprise entre 300 mPa.s et 100 000 mPa.s,
de préférence entre 400 et 64 000 mPa.s ;
• éventuellement, procéder à la coloration du matériau floqué.
2. Procédé selon la revendication 1, dans lequel ladite étape d'activation comprend l'immersion
des fibres coupées dans un bain d'une solution aqueuse comprenant des sels inorganiques.
3. Procédé selon la revendication 2, dans lequel suite au traitement d'activation, les
fibres coupées sont laissées sécher et, après séchage, se retrouvent avec une quantité
de sel inorganique comprise entre 0,5 et 2 % du poids initial.
4. Procédé selon l'une quelconque des revendications précédentes, dans lequel la couche
de support sur laquelle la couche d'agent adhésif est appliquée consiste en un tissu
orthogonal ou un tissu tricoté ou un tissu non tissé, de préférence un nylon non tissé
par filage direct ou un tissu polypropylène, ou un tissu composite élastomère non
tissé, de préférence de la microfibre en polyester dans une matrice de polyuréthanne,
ou un film composé de polyoléfine, de préférence de polypropylène ou de papier.
5. Procédé selon l'une quelconque des revendications précédentes, dans lequel l'agent
adhésif étant placé sur la couche de support est choisi parmi : une colle polyuréthanne
dans une dispersion aqueuse ou dans un solvant, une colle acrylique à base d'eau et
une colle silicone.
6. Procédé selon la revendication 8, dans lequel un pigment, de préférence un pigment
conducteur en mesure de faciliter le processus de flocage ultérieur, et/ou des additifs
en mesure de faciliter l'adhésion à la fibre bicomposée, sont ajoutés au dit agent
adhésif.
7. Procédé selon l'une quelconque des revendications précédentes, dans lequel ledit flocage
électrostatique des fibres coupées sur la couche d'agent adhésif se déroule dans un
environnement ayant un niveau d'humidité contrôlé et constant compris entre 60 et
90 %, de préférence entre 70 et 80 %, avec l'application d'un champ électrostatique
compris entre 20 et 50 kV, de préférence entre 20 et 40 kV.
8. Procédé selon la revendication 10, dans lequel la quantité de fibres coupées déposées
sur le substrat est comprise entre 50 et 250 g/cm2, de préférence entre 140 et 190 g/cm2.
9. Procédé selon l'une quelconque des revendications précédentes, dans lequel ledit agent
détachant comprend une base, de préférence NaOH, ou un acide, de préférence un acide
formique, de préférence mélangé à un polysaccharide.
10. Procédé selon l'une quelconque des revendications précédentes, dans lequel ledit agent
détachant est appliqué sur les fibres floquées selon une quantité comprise entre 80
et 150 g/m2.
11. Procédé selon l'une quelconque des revendications précédentes, dans lequel suite à
l'application de l'agent détachant, le matériau est thermiquement traité avec un courant
de vapeur saturée, des radiofréquences, des microondes ou thermiquement avec de l'air
chaud.
12. Procédé selon l'une quelconque des revendications précédentes, dans lequel la viscosité
de ladite couche de résine amovible est supérieure à celle dudit agent détachant et
de préférence comprise entre 1 000 mPa.s et 150 000 mPa.s.
13. Matériau floqué comprenant :
- une couche de support, de préférence en tissu ou en tissu non tissé ;
- une couche adhésive appliquée sur la surface de la couche de support ou une partie
de celle-ci ;
- une couche fibreuse comprenant une pluralité de fibres île-mer étant de préférence
orientées dans une direction perpendiculaire à la couche de support, partiellement
immergées dans la couche adhésive et ayant le composant mer toujours présent dans
la partie de fibres immergées à l'intérieur de la couche adhésive et totalement ou
partiellement absent dans la section de fibres émergeant de la couche adhésive.
14. Matériau floqué selon la revendication 16, dans lequel ladite couche adhésive est
d'une épaisseur comprise entre 0,05 et 0,50 mm, de préférence entre 0,10 et 0,35 mm.
15. Matériau floqué selon la revendication 16 ou 17, dans lequel ladite pluralité de fibres
mer-île sont incluses à l'intérieur de la couche adhésive selon une profondeur comprise
entre 40 microns et l'épaisseur totale de la couche adhésive.
16. Matériau floqué selon l'une quelconque des revendications de 16 à 18, dans lequel
le composant île des fibres mer-île comporte un titre compris entre 0,04 et 0,30 dtex.
17. Utilisation d'un matériau floqué selon l'une quelconque des revendications de 16 à
19, dans les domaines de l'automobile, de l'ameublement et de l'électronique grand
public, remplaçant toutes les parties actuellement revêtues de tissus, non tissés
ou de cuirs, de préférence pour recouvrir des surfaces et des structures de revêtement
des intérieurs de véhicules à moteur, des objets de décoration d'intérieur (cloisons,
sofas, fauteuils, etc.), sacs à main, valises ou tout autre accessoire, étuis ou housses
pour armes, instruments de musique, appareils électroniques, ou pour faire des tapis.