This application is the U.S. national phase entry under 35 U.S.C. § 371 of International Application No. PCT/FR2017/051012, filed on Apr. 28, 2017, which claims priority to French Patent Application No. 1653866, filed on Apr. 29, 2016; French Patent Application No. 1653870, filed Apr. 29, 2016; French Patent Application No. 1653872, filed Apr. 29, 2016; French Patent Application No. 1653873, filed Apr. 29, 2016; French Patent Application No. 1653888, filed Apr. 29, 2016; French Patent Application No. 1653894, filed Apr. 29, 2016; and French Patent Application No. 1653897, filed Apr. 29, 2016; the entireties of each of which are herein incorporated by reference.
The present disclosure relates to the field of closure systems, and more particularly it relates to closure systems with hooks and to associated methods and apparatuses for fabricating them.
Conventional methods and apparatus for making closure systems comprising self-gripping elements such as hooks conventionally use means for extruding plastics material in a continuous profile and then cutting it and deforming it in the longitudinal direction in order to form the hooks.
Those successive steps would require in particular a plurality of heating and cooling steps during the method, which leads to complexification and to a consequent increase in the dimensions of the apparatus needed for manufacturing.
In addition, each cooling step contributes to increasing the occupation time of the device, which is penalizing. Furthermore, the need to cool the material between the various steps of the method and therefore between the various workstations of the installation leads to the production line being slowed down.
In addition, the workstations and cutting steps consequently lead to an increase in the dimensions of the apparatus, thereby making it very complex to install.
Furthermore, the various manufacturing methods are commonly limited in terms of the shape of the retaining elements, the shape of the retaining elements for example being determined by structural elements of the apparatus associated therewith that cannot be modified easily by the user without requiring consequent modification of the apparatus.
The present disclosure thus seeks to address these various problems.
In a first aspect, the present disclosure relates to a retaining device comprising:
the device being characterized in that
In an example, the head of each retaining element includes a catch portion extending radially relative to the top end of the stem, said rib extending at least in part over the catch portion.
In an example, the head of each retaining element includes two catch portions extending radially relative to the top end of the stem, each of said catch portions including a rib, said catch portions extending on either side of the stem.
The head may then include a rib extending continuously between the two catch portions.
In an example, the head further includes a transverse rib extending between two opposite ends of the head on either side of an axis extending in the longitudinal direction and passing via the stem and/or the head, typically via the middle of the stem and/or of the head, the transverse rib extending over the top end of the stem.
In an example, the at least one catch portion includes a downwardly sloping free end.
In an example, the top face of the head of each retaining element as two distinct rims extending at least in part over the same catch portion.
In an example, for each retaining element, each of the ribs extends over a fraction only of the periphery of the head, in particular the combined length of the ribs of a retaining element under consideration lies in the range 5% to 95% of the length of the periphery of the head of the retaining element under consideration, more particularly in the range 30% to 85% of the length of the periphery of the head of the retaining element under consideration.
In an example, said base has two edges in the longitudinal direction, and wherein each of said edges presents highs and lows, the maximum offset between the highs and the lows along a direction transverse to the longitudinal direction being less than 1 millimeter (mm) over a length in the longitudinal direction that corresponds to three consecutive highs.
In an example, the width of the base lies in the range 1 mm to 500 mm, more particularly in the range 3 mm to 100 mm.
In an example, the retaining elements have a height lying in the range 5 μm to 5000 μm, or indeed in the range 5 μm to 2000 μm, or more particularly in the range 20 μm to 800 μm, with height being measured in a direction perpendicular to the top face of the base.
In an example, the stem of each retaining element presents symmetry of rotation about an axis perpendicular to the top face of the base.
In an example, each rib of the head extends in a direction that is substantially transverse (i.e. to within ±30°) to said longitudinal direction of the base.
In an example, the retaining elements present a shape that is asymmetrical relative to a plane that is transverse to the longitudinal direction of the base.
In an example, each retaining element presents symmetry relative to a plane extending in a longitudinal direction of the base and containing the axis of the stem of the retaining element. This rib is arranged in such a manner as to reinforce of the head of the hook, in particular its catch portions, in order to facilitate inserting and/or passing fibers or filaments under the head so as to enable them to be retained. The height of the rib (measured along a direction perpendicular to the plane of the base) lies typically in the range 0.005 mm to 0.1 mm, preferably in the range 0.01 mm to 0.08 mm. The term “rib” designates a longitudinal portion that extends, in its height direction, from the surface of the head substantially away from the base. This represents a length (measured substantially along the longitudinal direction) that is greater than its width (measured substantially along a transverse direction). More particularly, the ratio of the width over the length of the rib is strictly less than 1. In other words, the rib forms a projection from the top surface of the hook in such a manner that the top surface of the hook is not flat.
In an example, each catch portion extends in a direction that is substantially perpendicular to the longitudinal direction of the base.
In an example, each rib, seen from above the hook, presents a V-shape in which the angle between the two branches of the upside down V-shape (or U-shape or C-shape) lies in the range 90° to 180°, more particularly in the range 110° to 170°, or more precisely in the range 140° to 150°. The tip of the upside down V-shape is typically situated towards the front of the hook in the longitudinal direction.
In an example, the length of at least one rib in a direction transverse to the longitudinal direction of the base is greater than the diameter of the stem in a direction perpendicular to the longitudinal direction of the base.
In a second aspect, the present disclosure relates to a retaining device with hooks comprising
the device being characterized in that:
In an example, in section view on a direction transverse to the longitudinal direction, said edges present portions of rounded shape.
In an example, the maximum offset between the highs and the lows in a direction transverse to the longitudinal direction and over a length in the longitudinal direction corresponding to three successive highs, said maximum offset lies in the range 0.001 mm to 1.0 mm, more particularly the range 0.001 mm to 0.5 mm, still more particularly in the range 0.001 mm to 0.1 mm.
In an example, the three consecutive highs are over a distance that is less than the distance corresponding to 15 times the hook pitch, preferably less than a distance of 25.0 mm.
In an example, the width of the base measured in a direction transverse to the longitudinal direction lies in the range 1 mm to 500 mm, more particularly in the range 3 mm to 100 mm.
In an example, the retaining elements have a height lying in the range 5 μm to 5000 μm, or indeed in the range 5 μm to 2000 μm, or more particularly in the range 20 μm to 800 μm, or still more particularly in the range 100 μm to 500 μm, with height being measured in a direction perpendicular to the top face of the base.
In an example, the stem of each retaining element presents symmetry of rotation about an axis perpendicular to the top face of the base.
In an example, each of the retaining elements is formed by a stem surmounted by a head, the stem having a bottom end connected to the base, and a top end opposite from the bottom end, the head surmounting the top end of the stem, and having a bottom face facing towards the base and a top face opposite from the bottom face, and wherein the top face of the head of each retaining element includes a rib.
In an example, the retaining elements present a shape that is asymmetrical relative to a direction that is transverse to the longitudinal direction of the base.
In an example, each retaining element presents symmetry relative to a plane extending in a longitudinal direction of the base and containing the axis of the stem of the retaining element. The base of the tape is thus free from any extra thickness extending continuously along its edges, and typically presents a thickness that is substantially constant from one edge to the other. A thickness is said to be “substantially” constant when that thickness presents variation of less than 15%. More generally, it can be understood that the base of the tape may be free from any non-functional extra thickness (or from any extra thickness having the sole function of improving the regularity of the margins of the tape), which is advantageous in production terms in so far as extra thickness leads to overconsumption of material and increases the length of time the molds are occupied.
In an example, the device further comprises a layer of nonwoven material secured to the bottom face of the base and/or to the top face of the base, and wherein fractions of fibers and/or filaments of the layer of nonwoven material are encapsulated in the base.
In an example, the device further comprises a plastics film or an elastic film or a composite film secured to the bottom face of the base, the surface area of the film in contact with the bottom face of the base being greater than the projection of the surface area of the film onto a plane defined by the bottom face of the base.
In a third aspect, the present disclosure relates to a method of assembling an assembly comprising a tape of retaining elements and a substrate, said method comprising the following steps:
In an example, during the step of applying a substrate against the bottom face of the base, the bottom face of the base, upstream from the application step, is at a temperature that is lower than its melting temperature, or more particularly lower than the heat deflection temperature of the material forming the base, and the temperature of the base results solely from the step of forming the tape.
In an example, during the step of applying the substrate against the bottom face of the base, the base is at a surface temperature lying between the melting temperature of the material constituting the base and the Vicat B softening temperature of the material constituting the base minus 30° C., more particularly between the melting temperature of the material constituting the base and the Vicat A softening temperature of the material constituting the base, or indeed in the range 75° C. to 150° C., in particular substantially equal to 105° C. for a base made of polypropylene.
In an example, during the step of applying the substrate against the bottom face of the base, pressure is applied by means of a roller.
In an example, the method includes a subsequent step of unmolding the assembly formed by the tape of retaining elements and the substrate.
In an example, the substrate is a layer of nonwoven material, and wherein portions of fibers and/or filaments of the layer of nonwoven material are encapsulated in the base.
The step of applying the substrate against the bottom face of the base prior to solidification of said bottom face of the base is then typically performed in such a manner as to cause portions of fibers and/or filaments of the nonwoven layer to penetrate into the base, at least in part.
In a variant, the substrate is a plastics film, an elastic film, or a composite film.
The step of applying the substrate against the bottom face of the base prior to solidification of said bottom face of the base is then typically performed in such a manner that the surface area of the substrate in contact with the bottom face of the base is greater than the surface area of the substrate projected onto the bottom face of the base, in particular once the base has cooled.
In an example, following the step of applying the substrate, the base and the hooks are cooled in such a manner as to cause the material forming the base to shrink, thereby causing local deformation of the bottom face of the base, this deformation giving rise to deformation of the top face of the substrate secured thereto.
In another variant, the substrate is a set of thermally-consolidated fibers and/or filaments.
In an example, the substrate is applied in non-uniform manner against the bottom face of the base so as to obtain non-uniform bonding between the base and the substrate.
In an example, the substrate is applied in uniform manner against the bottom face of the base so as to obtain substantially uniform bonding between the base and the substrate.
In an example, the step of forming the tape of retaining elements makes elements in relief projecting from and/or recessed in the bottom face of the base and distinct from the retaining elements, and wherein the step of applying the substrate against the bottom face of the base provides bonding between the substrate and the base via said elements in relief.
In an example, during the step of forming the tape of retaining elements;
In an example, during unmolding, the strip and the first preforms are unmolded in such a manner as to deform the first preforms plastically so as to obtain second preforms of shape that is different from the first preforms.
It is then possible, after the unmolding step, to perform a forming step during which the unmolded tape is inserted into a forming device so as to modify the shape of the heads of the second preforms by forming.
The step of dispensing the molding material is typically performed in such a manner as to form a tape extending in a longitudinal direction and comprising a base presenting two edges in the longitudinal direction, each of the edges presenting highs and lows, wherein the maximum offset between the highs and the lows is less than 1.0 mm over a length in the longitudinal direction corresponding to three consecutive highs, and wherein the step of applying the substrate against the bottom face of the base conserves this maximum offset in a direction transverse to the longitudinal direction between the highs and lows at less than 1 mm over a length in the longitudinal direction corresponding to three consecutive highs.
This third aspect also provides apparatus for performing a method as described above;
In an example, said drive means comprise at least one roller.
Said roller is typically configured so as to press in non-uniform manner against the bottom face of the base so as to provide non-uniform bonding between the base and the substrate.
This third aspect also provides a retaining device, comprising a plastics tape extending in the longitudinal direction comprising a base presenting a bottom face and a top face and including a plurality of retaining elements extending from said top face, and a substrate secured to the bottom face of the base;
the retaining device being characterized in that the substrate penetrates into the base beyond a mean plane defined by the bottom face of the base of the tape.
In an example, the substrate is a layer of nonwoven material, and wherein portions of fibers and/or filaments of the layer of nonwoven material are encapsulated in the base.
In a variant, the substrate is a plastics film, an elastic film, or a composite film, and wherein the surface area of the film in contact with the bottom face is greater than the surface area of the projection of the surface of the film onto a plane defined by the bottom face of the base.
In a fourth aspect, the present disclosure provides a method of forming a retaining device with hooks, wherein:
In an example, after the unmolding step, a forming step is performed during which the unmolded tape is inserted into a forming device so as to modify the shape of the heads of the second preforms by forming.
In an example, the forming device comprises at least two rotary elements, each of said rotary elements having a speed that is different from the drive speed of the tape.
In an example, the molding material is polypropylene, and wherein during the forming step, at least one forming element of the forming device is maintained at a temperature lying in the range 75° C. to 165° C., in particular substantially equal to 120° C., or indeed substantially equal to 140° C., or more precisely substantially equal to 150° C.
In an example, the step of unmolding the tape and the first preforms leads to a change in the height of the head and/or of the stem, and/or to a change in the width of the head and/or of the stem.
In an example, the forming device comprises an element at ambient temperature (or at a non-regulated temperature), and at least one element at a temperature that lies strictly between the heat deflection temperature (HDT) and the melting temperature of the molding material.
In an example, the forming step produces at least one deformation of a portion of the head of each of the second preforms, said deformation tending, for each preform, to deform one of the ends of the head of the preform so as to form a rib on the top face of the head of the preform.
In an example, during the step of dispensing the molding material, the gap between the material dispenser means and the molding strip lies in the range 10 μm to 700 μm, more particularly in the range 10 μm to 500 μm, or more precisely in the range 50 μm to 100 μm.
In an example, the step of dispensing the molding material is performed in such a manner that the molding material is dispensed while the inside face of the molding strip is bearing against a molding strip drive roller.
In an example, the step of dispensing the molding material is performed through a sheet of nonwoven material arranged on the molding strip, said sheet of nonwoven material including empty zones allowing the molding material to pass through.
The molding material is then typically polypropylene or a formulation based on polypropylene, and the step of dispensing the molding material is typically performed at a pressure lying in the range 10 bar to 100 bar, or indeed in the range 30 bar to 50 bar, and at a temperature lying in the range 150° C. to 300° C.
The molding strip is then typically driven at a travel speed lying in the range 1 meter per minute (m/min) to 500 m/min, more particularly in the range 5 m/min to 250 m/min.
In an example, the unmolding step is performed while the base of the tape is at a temperature lower than the melting temperature of the molding material, or lower than the heat deflection temperature of the molding material.
In an example, the step of dispensing the molding material is performed so as to form a tape extending in a longitudinal direction and comprising a base presenting two edges in the longitudinal direction, each of the edges presenting highs and lows, wherein the maximum offset between the highs and the lows in a direction transverse to the longitudinal direction is less than 1.0 mm over a length in the longitudinal direction corresponding to three consecutive highs.
In an example, prior to the unmolding step, a layer of nonwoven material is applied against the bottom face of the base before the bottom face of the base has solidified so as to cause portions of the fibers and/or filaments of the layer of nonwoven material to penetrate into the base, at least in part.
During the step of applying the nonwoven material against the bottom face of the base, the layer of nonwoven material is then typically at ambient temperature (or at a temperature that is not regulated), and the temperature of the base is the result only of the step of forming the tape.
During the step of applying the layer of nonwoven material against the bottom face of the base, the bottom face of the base is typically at a temperature lower than its melting temperature.
This fourth aspect also provides apparatus for performing a method as defined above, and comprising:
In an example, the apparatus further comprises a forming device configured to modify the heads of the preforms by forming.
In an example, the apparatus further comprises drive means for driving a layer of nonwoven material and adapted to press a nonwoven material against the bottom face of the base of the tape of retaining elements downstream from the material dispenser means.
This fourth aspect further provides apparatus for forming a retaining device with hooks, the apparatus comprising:
the molding strip and the unmolding means being configured so that unmolding the strip of preforms leads to the first preforms being deformed in such a manner as to form second preforms of a shape that is different from the first preforms.
In an example, this apparatus further comprises a forming device configured to modify the heads of the preforms by forming.
In an example, the forming device comprises at least two rotary elements, one of said rotary elements including heater means or temperature regulator means configured so as to maintain it at a temperature that lies strictly between the heat deflection temperature and the melting temperature of the molding material.
In another embodiment, the head may be heated prior to the forming step so that it is at a temperature lying between the heat deflection temperature of the molding material and the melting temperature of the molding material, the forming device including an element operating at a temperature that is less than the heat deflection temperature of the molding material, for example.
In an example, said rotary elements of the forming device have respective speeds that are different from that of the molding device.
In an example, the forming means are configured so as to form at least one fold in the head of each preform. More particularly, said at least one fold tends to fold at least one end of the head of the preform towards a central portion of the head of the preform.
In an example, the forming device comprises a rotary element configured in such a manner as to operate at ambient temperature or at a non-regulated temperature, and at least one a rotary element having heater means adapted so that said at least one rotary element operates at a temperature that lies strictly between the heat deflection temperature and the melting temperature of the molding material.
In an example, the rotary elements of the forming device are configured so as to be driven in rotation at distinct speeds of rotation, the rotary element having the lower temperature having a relative speed that is different from the rotary element(s) having a higher temperature.
In an example, the cavities of the molding strips extend in a cavity direction that is substantially perpendicular to the outside face of the molding strip, and each defines a stem and a head, each presenting symmetry of rotation about said cavity direction, the head having a dimension that is greater than the maximum dimension of the stem as measured radially relative to the cavity direction.
In an example, the material dispenser means are configured so as to dispense the molding material at a point of the molding strip while the inside face of the molding strip is pressing against a roller of the rotary drive means.
In an example, the gap between the material dispenser means and the molding strip lies in the range 10 μm to 700 μm, more particularly in the range 20 μm to 500 μm, or more precisely in the range 50 μm to 100 μm.
In an example, the rotary drive means for driving the molding strip comprise at least two rollers, each having a diameter lying in the range 10 times to 10,000 times the thickness of the molding strip, in particular in the range 50 times to 5000 times the thickness of the molding strip, e.g. in the range 100 mm to 250 mm.
In an example, the apparatus further comprises means for pressing a strip of nonwoven material and/or of woven material and/or of knitted material against the molding strip upstream from the material dispenser means.
In an example, the cavities in the molding strip are through cavities.
In an example, the apparatus further comprises a scraper device arranged on the inside face of the molding strip, downstream from the material dispenser means.
In an example, the molding strip includes an inner strip made of rubber forming its inside face, the ends of the cavities of the molding strip being formed in said inner strip made of rubber.
In a fifth aspect, the present disclosure provides a method of forming a retaining device with hooks, wherein:
In an example, during the step of unmolding the tape and the first preforms, the first preforms are deformed plastically so as to obtain second preforms of shape that is different from the shape of the first preforms, said second preforms subsequently being deformed by the forming device.
In an example, the forming device comprises at least two rotary elements, each of said rotary elements having a speed that is different relative to the tape.
In an example, the molding material is polypropylene, and wherein during the forming step, at least one forming element of the forming device is maintained at a temperature lying in the range 75° C. to 165° C., and in particular close to 120° C.
In an example, the step of unmolding the tape and the first preforms leads to a change in the height of the head and/or of the stem, and/or to a change in the width of the head and/or of the stem.
In an example, the forming device comprises an element at ambient temperature or at a non-regulated temperature, and at least one element at a temperature that lies strictly between the heat deflection temperature (HDT) and the melting temperature of the molding material.
In an example, the forming step produces at least one deformation of a portion of the head of each of the second preforms, said deformation tending, for each preform, to deform one of the ends of the head of the preform so as to form a rib on the top face of the head of the preform.
In an example, the step of dispensing the molding material is performed in such a manner that the molding material is dispensed while the inside face of the molding strip is bearing against a molding strip drive roller.
In an example, the step of dispensing the molding material is performed through a sheet of nonwoven material arranged on the molding strip, said sheet of nonwoven material including empty zones allowing the molding material to pass through.
In an example, during the step of dispensing the molding material, the gap between the material dispenser means and the molding strip lies in the range 10 μm to 700 μm, more particularly in the range 10 μm to 500 μm, or more precisely in the range 50 μm to 100 μm.
The molding material is then typically polypropylene, and the step of dispensing the molding material is typically performed at a pressure lying in the range 10 bar to 100 bar, or indeed in the range 30 bar to 50 bar, and at a temperature lying in the range 150° C. to 300° C.
The molding strip is then typically driven at a travel speed lying in the range 1 m/min to 500 m/min, more particularly in the range 5 m/min to 250 m/min.
In an example, the unmolding step is performed while the base of the tape is at a temperature lower than the melting temperature of the molding material, or lower than the heat deflection temperature of the molding material.
In an example, the step of dispensing the molding material is performed so as to form a tape extending in a longitudinal direction and comprising a base presenting two edges in the longitudinal direction, each of the edges presenting highs and lows, wherein the maximum offset between the highs and the lows in a direction transverse to the longitudinal direction is less than 1.0 mm over a length in the longitudinal direction corresponding to three consecutive highs.
In an example, prior to the unmolding step, a layer of nonwoven material is applied against the bottom face of the base before the bottom face of the base has solidified so as to cause portions of the fibers and/or filaments of the layer of nonwoven material to penetrate into the base, at least in part.
In an example, during the step of applying the nonwoven material against the bottom face of the base, the layer of nonwoven material is at ambient temperature or at a temperature that is not regulated, and the temperature of the base is the result only of the step of forming the tape.
In an example, during the step of applying the strip of nonwoven material against the bottom face of the base, the bottom face of the base is at a temperature lower than its melting temperature.
This fifth aspect also provides apparatus for performing a method as defined above, and comprising:
In an example, the molding strip and the unmolding means are configured so that unmolding the strip of preforms leads to the first preforms being deformed in such a manner as to form second preforms of a shape that is different from the first preforms.
In an example, the apparatus further comprises drive means for driving a layer of nonwoven material and adapted to press a nonwoven material against the bottom face of the base of the tape of retaining elements downstream from the material dispenser means.
This fifth aspect also provides apparatus for forming a retaining device with hooks, the apparatus comprising:
the molding strip and the unmolding means being configured so that unmolding the strip of preforms leads to the first preforms being deformed in such a manner as to form second preforms of a shape that is different from the first preforms.
In an example, the apparatus further comprises a forming device configured to modify the heads of the preforms by forming.
In an example, the forming device comprises at least two rotary elements, one of said rotary elements including heater means or temperature regulator means configured so as to maintain it at a temperature that lies strictly between the heat deflection temperature and the melting temperature of the molding material.
In an example, said rotary elements of the forming device have respective speeds that are different from that of the molding device.
In an example, the forming means are configured so as to form at least one fold on the head of each preform, said at least one fold tending to fold at least one end of the head of the preform towards a central portion of the head of the preform.
In an example, the forming device comprises a rotary element configured in such a manner as to operate at ambient temperature or at a non-regulated temperature, and at least one rotary element having heater means adapted so that said at least one rotary element operates at a temperature that lies strictly between the heat deflection temperature and the melting temperature of the molding material.
In an example, the rotary elements of the forming device are configured so as to be driven in rotation at distinct speeds of rotation.
In an example, the cavities of the molding strips extend in a cavity direction substantially perpendicular to the outside surface of the molding strip, and each defines a stem and a head, each presenting symmetry of rotation about said cavity direction, the head having a dimension that is greater than the maximum dimension of the stem as measured radially relative to the cavity direction.
In an example, the material dispenser means are configured so as to inject the molding material at a point of the molding strip while the inside face of the molding strip is pressing against a roller of the rotary drive means.
In an example, the gap between the material dispenser means and the molding strip lies in the range 10 μm to 700 μm, more particularly in the range 20 μm to 500 μm, or more precisely in the range 50 μm to 100 μm.
In an example, the rotary drive means for driving the molding strip comprise at least two rollers, each having a diameter lying in the range 10 times to 10,000 times the thickness of the molding strip, in particular in the range 50 times to 5000 times the thickness of the molding strip, e.g. in the range 100 mm to 250 mm.
In an example, the apparatus further comprises means for pressing a strip of nonwoven material against the molding strip upstream from the material dispenser means.
In an example, the cavities in the molding strip are through cavities.
In an example, the apparatus further comprises a scraper device arranged on the inside face of the molding strip, downstream from the material dispenser means.
In an example, the molding strip includes an inner strip made of rubber forming its inside face, the ends of the cavities of the molding strip being formed in said inner strip made of rubber.
In a sixth aspect, the present disclosure relates to a retaining device comprising
a plastics tape extending in the longitudinal direction comprising a base presenting a bottom face and a top face and including a plurality of retaining elements extending from said top face;
the retaining device being characterized in that the film, the base, and the retaining elements are formed integrally by means of extrusion.
In an example, the film, base, and the retaining elements are formed integrally by successive and/or simultaneous extrusion operations.
In an example, the transition between the elastic film and the base of the tape, beside the top face and/or the bottom face, is continuous.
In an example, the plastics tape and the elastic film form an intermediate layer having a bottom face and a top face, said device further comprising a layer of nonwoven material secured to at least a portion of the bottom face of the intermediate layer.
The securing is then typically performed by partial encapsulation in said intermediate layer.
The partial encapsulation is typically performed in the elastic film of the intermediate layer.
The partial encapsulation is typically performed in the plastics tape of the intermediate layer. The partial encapsulation may be performed in the plastics tape of said intermediate layer and in the elastic film of said intermediate layer.
In an example, the device further comprises a nonwoven layer secured to the top face of the intermediate layer.
The nonwoven layer is then typically secured to the top face of the intermediate layer by means of adhesive.
In an example, at least one of the bottom face and/or of the top face of the intermediate layer presents elements projecting from said face, which projecting elements are distinct from the retaining elements.
The projecting elements are typically in the form of spikes.
In an example, the base of the plastics tape presents a thickness lying in the range 10 μm to 700 μm, where the thickness is the distance between the top face and a bottom face, each of the retaining elements is constituted by a stem and by a head;
the stem having a bottom end connected to the base, and a top end opposite from the bottom end, the head surmounting the top end of the stem, and having a bottom face facing towards the base and a top face opposite from the bottom face, and wherein the top face of the head of each retaining element includes a rib.
In an example, the nonwoven layer is activated. The nonwoven material may be activated prior to lamination or indeed the laminate may be activated over its entire width.
This sixth aspect also provides a method of forming a retaining device with hooks, wherein:
in such a manner that the plastics tape and the elastic film and the retaining elements are made integrally by extrusion, the tape of plastics material and the elastic film forming an intermediate layer.
In an example, the elastic film is formed to extend the tape.
In an example, after making the intermediate layer, a step is performed of applying a nonwoven layer against the bottom face of the intermediate layer before said bottom face of the intermediate layer solidifies, in such a manner as to cause portions of fibers and/or filaments of the nonwoven layer to penetrate at least in part into the intermediate layer.
During the step of applying the nonwoven layer against the bottom face of the intermediate layer, the layer of nonwoven material is typically at ambient temperature or at a non-regulated temperature, and the temperature of the bottom face of the intermediate layer is the result solely of the step of making the intermediate layer.
In an example, the method includes the step of applying a layer of nonwoven material against the top face of the intermediate layer.
The layer of nonwoven material is then typically bonded to the top face of the intermediate layer, typically by using an adhesive.
In an example, prior to forming the intermediate layer, a support layer is positioned on at least a portion of the molding device.
In an example, the method includes a prior step of activating the layer(s) of nonwoven material.
In an example, prior to dispensing material, a molding strip is provided presenting an inside face and an outside face, and having a plurality of cavities, each cavity defining a stem extending from the outside face towards the inside face, and including an end that forms a head extending from the end of the stem towards the inside face of the molding strip, the molding strip is positioned on rotary drive means, e.g. comprising at least two rollers, the inside face of the molding strip being arranged to press against the drive means;
wherein the dispensing of material is followed by an unmolding step in which the tape and the first preforms are unmolded in such a manner as to deform the first preforms plastically so as to obtain second preforms of shape that is different from the shape of the first preforms.
After the unmolding step, a forming step is typically performed during which the unmolded tape is inserted into a forming device so as to modify the shape of the heads of the second preforms by forming.
Other characteristics, objects, and advantages of the present disclosure appear from the following description, which is purely illustrative and non-limiting, and which should be read with reference to the accompanying drawings, in which:
In all of the figures, elements that are in common are identified by identical numerical references.
The apparatus as shown comprises a molding strip 1 positioned on rotary drive means 2 comprising in this example two rollers 21 and 22, and material dispenser means 3 adapted to inject molding material, which may for example be a plastics material and/or an elastic material.
The unit formed by the molding strip 1 and the rotary drive means 2 thus forms a molding device.
The example shown comprising two rollers 21 and 22 is not limiting, it being possible to vary the number and the arrangement of the roller(s), in particular in order to adapt to the length of the molding strip 1 and to the various stations of the apparatus. By way of example, it would be possible to use three rollers, or indeed only one, such that the molding strip is arranged on the periphery of a single roller. In particular, only one of the two rollers need be driven in rotation by motor means, e.g. the roller 21, the other roller 22 being free, i.e. without motor means, and being driven in rotation by the molding strip, itself driven by the roller 21.
The molding strip 1 as shown comprises an inside face 11 and an outside face 12, the inside face 11 being in contact with the rotary drive means 2.
The material dispenser means 3 are arranged to inject the molding material onto the outside face 12 of the molding strip 1.
More precisely, the material dispenser means 3 are arranged facing the molding strip 1, being spaced apart from the molding strip 1 so as to define a gap e shown in
The molding strip 1 is provided with a plurality of cavities for making the hooks of the retaining device with hooks.
Each cavity 13 is formed in such a manner as to define a stem 14 extending from the outside face 12 of the molding strip 1 towards its inside face 11, together with a head 15 extending between the stem 14 and the inside face 11 of the molding strip 1.
In the example shown, the heads 15 of the cavities 13 open out into the inside face 11 of the molding strip 1. The cavities 13 are thus through cavities. Such an embodiment is not limiting, it being equally possible for the cavities 13 to be blind cavities, and thus for them not to open out into the inside face 11 of the molding strip 1.
The portions of the cavity 13 that form the stem 14 typically extend in a direction perpendicular to the outside face 12 of the molding strip 1. The portions of the cavities 13 forming the stem 14 are typically shapes of revolution around an axis perpendicular to the outside face 12 of the molding strip 1, or shapes that present a plane of symmetry extending in a direction parallel to the travel direction of the molding strip 1 and/or in a direction perpendicular to the travel direction of the molding strip 1.
By way of example, the portions of the cavities 13 forming the stems 14 are generally frustoconical or circularly cylindrical in shape about an axis perpendicular to the outside face 12 of the molding strip 1, and each of them presents a rounded fillet at the junction with the outside face 12 of the molding strip 1.
The portions of the cavities 13 forming the heads 15 typically extend radially or transversely relative to an axis perpendicular to the outside face 12 of the molding strip 1, and they may present symmetry of rotation about this axis perpendicular to the outside face 12 of the molding strip 1. The portions of the cavities 13 forming the heads 15 typically present a shape that is substantially frustoconical or hexahedral.
The portions of the cavities 13 forming the heads 15 may be linear or rounded, e.g. to form portions that are curved towards the inside face 11 or towards the outside face 12 of the molding strip 1 extending from the portions of the cavities 13 forming the stems 14.
The portions of the cavities 13 forming the heads 15 may present a thickness that is constant or varying.
In the example shown in the figures, the portions of the cavities 13 forming the head 15 extend radially around the portions of the cavities 13 forming the stems 14, and they present the general shape of a disk, as can be seen in particular in
On its inside face 11 or on its outside face 12, the molding strip 1 may present particular texturing, such as slots, an array of grooves, or an array of passages forming vents or spikes, or it may be substantially smooth.
The molding strip 1 may be made up by superposing a plurality of strips, and it is thus not necessarily a single piece or made of a single material.
The material dispenser means 3 are typically arranged so as to inject molding material into the molding strip 1 at a section of the molding strip 1 where it bears against a drive roller, specifically the drive roller 21 in the example shown in
When the molding material is injected while the molding strip 1 is not bearing against a drive roller, then the material dispenser means 3 may include a base arranged on the other side of the molding strip 1, so that the inside face 11 of the molding strip 1 bears against the base while material is being injected, the base then forming a bottom for the cavities 13 of the molding strip 1.
The molding strip 1 typically presents a thickness lying in the range 5 μm to 5000 μm, or indeed in the range 5 μm to 2000 μm, or more precisely in the range 20 μm to 800 μm, or indeed in the range 100 μm to 500 μm.
In the longitudinal direction, the molding strip may present a length lying in the range 0.5 meters (m) to 5 m.
In the transverse direction, the molding strip may present a width lying in the range 5 mm to 3000 mm.
Each of the rollers 21 and 22 typically presents a diameter lying in the range 10 times to 10,000 times the thickness of the molding strip 1, or indeed 50 times to 5000 times the thickness of the molding strip 1, more precisely a diameter lying in the range 50 mm to 750 mm, or more particularly a diameter lying in the range 100 mm to 300 mm.
When compared with conventional forming means such as rollers in which the mold cavities are made directly, the use of a molding strip 1 associated with drive means 2 is advantageous for several reasons.
The use of a molding strip is particularly advantageous in terms of modularity. Specifically, the molding strip can be removed and replaced easily relative to the drive means, unlike a solid roller for which disassembly and reassembly operations are particularly complex to carry out. Such an advantage can be seen in particular when both rollers 21 and 22 are fastened at one end only to a frame, leaving the other end free for receiving and/or removing the molding strip. It is also possible to use guide means for the molding strip in order to facilitate inserting and/or removing it.
Furthermore, a molding strip is much easier to make in comparison with making a roller that includes molding cavities. Specifically, such rollers are typically made by stacking successive slices, thus requiring multiple machining operations and leading to major constraints both during assembly and on each occasion there is a change in the specification of the hooks, and such rollers present considerable weight, requiring them to be held at both ends, with the consequence of making them more complex to replace.
Furthermore, the use of a molding strip coupled to drive means makes it possible to make a molding device of considerable length while conserving fabrication and an installation that are simple, in particular when one of the rollers is mounted to be movable in translation so as to modify the offset between the rollers, and thus enable the tension of the molding strip to be adjusted. Conversely, making molding rollers of large diameter is typically complex, and leads to molding means of very great weight, thus implying that the entire assembly needs to be overdimensioned in order to be capable of supporting such rollers. Furthermore, making such molding rollers of large diameter does not make it possible to obtain acceptable dimensional tolerances.
The various steps in forming a retaining device with hooks by means of this apparatus are described below with reference to
As can be seen in
A layer of molding material is also deposited on the outside face 12 of the molding strip 1 so as to form a base for the retaining device, the thickness of this layer of molding material being determined by the gap e between the material dispenser means 3 and the molding strip 1.
The gap e typically presents a thickness lying in the range 10 μm to 700 μm, or typically in the range 10 μm to 500 μm, or indeed in the range 20 μm to 100 μm.
In the example shown, the cavities 13 in the molding strip 1 are through cavities. The apparatus may then include an element such as a scraper 4 positioned to scrape the inside face 11 of the molding strip 1 in order to remove excess molding material, as required. The term “injection” is used to designate the action of shaping a molding material by the melting technique, e.g. dispensing, delivering, molding, injecting, extruding.
Injecting molding material into the molding strip 1 by using the material dispenser means 3 thus makes it possible to form a base 51 and a plurality of elements or preforms, each comprising a stem 52 and a head 53, the assembly thus forming a tape 100. As described below, the elements comprising the stems 52 and the heads 53 are typically first preforms that are subsequently subjected to a shaping step in order to make hooks.
A longitudinal direction is defined relative to the travel direction of the tape 100, this longitudinal direction being parallel to the travel direction of the tape 100. This longitudinal direction is commonly referred to as the “machine direction” or “MD”. The longitudinal direction is designated by the axis MD in the figures.
A transverse direction is also defined, commonly referred to as the “cross direction” or “CD”, corresponding to a direction perpendicular to the longitudinal direction, and extending parallel to a plane face of the tape 100. The transverse direction is designated by the axis CD in the figures.
The base 51 presents a top face 511 and a bottom face 512 that are typically substantially parallel, the top face 511 being the face provided with hooks and/or preforms.
The base 51 typically presents a thickness lying in the range 10 μm to 700 μm, or typically in the range 20 μm to 500 μm, or indeed in the range 50 μm to 100 μm.
The base 51 typically presents a width lying in the range 1 mm to 3000 mm, or more precisely in the range 2 mm to 400 mm, or indeed between 3 mm and 100 mm, the width of the base 51 being measured along the direction that is transverse relative to the longitudinal direction, e.g. along a direction parallel to the outside face 12 of the molding strip 1.
It should be understood that these figures show the molding material as it is within the cavities 13, each time shown isolated from the molding strip 1 in order to show its shape in detail.
As can be seen in these figures, the hook preforms as formed in this way, specifically the first preforms, are each in the shape of a stem 52 of generally cylindrical or conical shape surmounted by a head 53.
A bottom end 521 of the stem 52 is defined, connecting the stem to the base 51, and a top end 522 of the stem 52 is defined opposite from the bottom end 521 of the stem 52.
The head 53 extends from the top end 522 of the stem 52.
In the example shown, the head 53 is hexagonal in shape with edges forming circular arcs. The head 53 thus has a plurality of portions extending radially from the top end 522 of the stem 52. The head 53, and more generally the assembly formed by the head 53 and the stem 52, thus presents symmetry of rotation about an axis passing through the center of the stem 52 and of the head 53. It is possible to envisage various other shapes for the head 53; the purpose of the example shown is merely to illustrate one embodiment. The head 53 may in particular be hexagonal in shape.
The apparatus as described and the associated method make it possible to operate at high tape formation speeds.
Specifically, conventional production lines for making retaining devices with hooks operate at low formation speeds, these low formation speeds being compensated by widening the tape that is being formed. This limit in terms of formation speed is the result in particular of the time needed for the injected material to solidify.
In contrast, the installation and the method as described make it possible to form a tape at a high formation speed, e.g. faster than 20 m/min, or indeed faster than 40 m/min, 60 m/min, 80 m/min, 100 m/min, 120 m/min, or 150 m/min, or indeed in the range 1 m/min to 500 m/min, or indeed in the range 5 m/min to 250 m/min. Specifically, the method described does not require the material that is injected to form the hooks to be cooled completely, and, moreover, using a molding strip of small thermal inertia, possibly presenting through cavities, makes it possible to improve considerably the rate at which the tape solidifies.
In an embodiment, the material dispenser means 3 may inject the molding material through a sheet of nonwoven material arranged on the outside face 12 of the molding strip 1.
A sheet of nonwoven material is then arranged on the outside face 12 of the molding strip 1 upstream from the material dispenser means 3. The sheet of nonwoven material may present empty zones to facilitate passing the molding material, and also zones that prevent the molding material from passing.
Such an embodiment thus makes it possible to obtain a tape presenting a layer of nonwoven material on its top face, i.e. its face presenting the retaining elements, i.e. the hooks. Injecting the molding material directly onto the sheet of nonwoven material thus makes it possible to ensure strong cohesion of the nonwoven material with the base 51.
Furthermore, by calibrating the distribution of the empty zones that facilitate passage of the molding material and of the zones that prevent passage of the molding material, it is possible to define a pattern for the distribution of the hooks.
The substrate in the calibrated zone typically presents air permeability that is greater than 2000 liters per square meter per second (L/m2/s), more particularly greater than 4000 L/m2/s in the hook-passing zone. This permeability characteristic is either intrinsic to the substrate, or else it is imparted to the substrate by treatment, by drilling, by punching, by needling, by suction, by embossing, or by some other technique. In an example, the substrate may be a nonwoven material, e.g. a printed nonwoven material. By way of example, the permeability of the substrate may be measured using the 1995 ISO 9237 standard at a pressure of 200 pascals (Pa) with 20 square centimeters (cm2) circular test pieces.
The weight of the nonwoven material typically lies in the range 2 grams per square meter (g/m2) to 45 g/m2. When the permeability of the nonwoven material is intrinsic, the permeability may be less than 15,000 L/m2/s, or indeed less than 7500 L/m2/s. The nonwoven material used is typically a nonwoven material of thickness lying in the range 0.10 mm to 0.8 mm, in particular in the range 0.20 mm to 0.60 mm. By way of example, the thickness of the nonwoven material may be measured in compliance with the 1997 standard NF EN ISO 9073-2 using its method A for normal nonwovens at a pressure of 0.5 kilopascals (kPa) and for a duration of 10 seconds (s).
The nonwoven material may also present weak mechanical strength, locally, or it may be mechanically weak intrinsically, such that the nonwoven material is perforated by the molding material when making the hooks or preforms.
The material dispenser means 3 may be adapted to dispense two distinct materials simultaneously or successively, thus making it possible to define two zones made of two distinct materials in the tape 100.
More precisely, the material dispenser means 3 may be adapted to inject simultaneously a molding material such as polypropylene for forming the base 51 and the hooks, and an elastic material for forming an elastic margin extending the base 51.
The molding strip 1 may then present suitable shapes for the various zones of the tape 100, for example it may present a portion provided with cavities 13 in order to form preforms or hooks corresponding to the portion where the molding material is injected, and a portion that does not present such cavities 13 corresponding to the portion where the elastic material is injected.
Because of the shape of the cavities, it can be understood that the heads 53 are necessarily deformed in order to enable them to be extracted from the molding strip 1.
The portions of the cavities 13 forming the stems 14 and the heads 15 are thus of dimensions suitable for allowing the heads 53 to pass through the portions of the cavities 13 that form the stems 14 in order to make unmolding possible.
Unmolding thus leads to the heads 53 being deformed, as shown diagrammatically in
The nature of the deformation depends particularly on the material used, and also on the shapes of the heads 53 and of the stems 52.
In order to reduce the force exerted on the preforms during unmolding, unmolding is typically performed in a zone where the molding strip is not in contact with one of the rollers 21 and 22.
In the example shown in
Thereafter,
In the example shown, unmolding the tape 100 has caused the head 53 to be deformed plastically so that its shape has been modified compared with the shape of the portion of the cavity 13 in which the head 15 was formed.
As can be seen in the figures, and in particular in
More particularly, at least a portion of the collar as formed in this way presents, in section view, an angle A of at least 15° between the mean axis of the portion under consideration of said collar and a plane parallel to the plane of the base 51. More particularly, this angle is greater than 35°, still more particularly greater than 45°. In
As a result of forming the collar, the maximum dimension of the head of the first preform as measured in a plane parallel to the plane of the base 51 (and referred to as the width of the head) is reduced by 10% to 150%, or indeed by 25% to 100% relative to the width of the head of the second preform and/or the diameter of the stem of the second preform.
The height of the head of the second preform is increased by 5% to 100%, or indeed by 12% to 50% relative to the height of the first preform, where height is measured along a plane perpendicular to the plane of the base 51.
In an example, the width of the head is decreased by 0.05 mm to 0.2 mm for a stem diameter of about 0.2 mm, where the stem diameters of the first and second preforms are substantially identical. The height of the head is increased by 0.025 mm to 0.1 mm for a stem diameter of about 0.2 mm, where the stem diameters of the first and second preforms are substantially identical.
It is thus considered that the step of injecting molding material into the molding strip 1 forms “first” preforms for the hooks, each comprising a stem 52 and a head 53 (e.g. as shown in
In the example shown in
The first or second preforms can then be adapted to perform the function of retaining means, or conversely not to present such properties.
Unmolding is typically performed when the base 51 of the tape 100 is at a temperature lower than the melting temperature of the molding material, or than the temperature at which the molding material bends under load, e.g. when the inside face 11 of the molding strip 1 is at a temperature of about 45° C. and the top face 511 of the base 51 is at a temperature of about 75° C. The temperature of bending under load is commonly referred to as the “heat deflection temperature” (HDT).
The unmolding step may be followed by a forming step in which the second preforms are modified, and in particular their heads 53 are modified.
The apparatus shown in
The forming device 7 as shown comprises a drive roller 71 and two forming rollers 72 and 73.
The function of the drive roller 71 is to guide and drive the tape 100. The function of the forming rollers 72 and 73 is to perform a forming action on the stems 52 and/or on the heads 53 of the preforms obtained by unmolding.
In the example shown, the forming device 7 comprises two forming rollers 72 and 73 serving to perform two successive forming steps that are described below. The forming device 7 is not limited to such an embodiment, and may have some other number of rollers, or more generally of forming means, in order to perform the desired forming steps. By way of example, the forming device 7 may be configured so as to perform a single deformation only, in which case it would have only one forming roller.
The forming rollers 72 and 73 are configured to exert mechanical and/or thermal force on the heads 53 and on the stems 52 of the preforms, so as to give rise to plastic deformation in order to confer a final shape to the hooks.
There follows a description of an example of forming, given with reference to
After unmolding, the tape 100 is driven by the drive roller 71 of the forming device 7. The forming rollers 72 and 73 are arranged so that each of them defines a passage between the forming roller in question and the drive roller 71 through which the tape 100 can pass.
These passages between the drive roller 71 and the forming rollers 72 and 73 are dimensioned so as to be smaller than the height of the tape 100, or where appropriate, than the height of the tape 100 and of the substrate, so that the forming rollers 72 and 73 exert a force on the preforms.
In the example shown, the two forming rollers 72 and 73 serve to perform two successive deformation steps on the preforms.
Each of the forming rollers 72 and 73 is driven in rotation at a speed of rotation that is distinct from the speed of rotation of the drive roller 71, and thus also distinct from the travel speed of the tape 100.
Taking the speed of the drive roller 71 as a reference speed, the first forming roller 72 possesses a tangential speed that is less than that of the drive roller 71, e.g. in the range 5% to 200% less than the speed of the drive roller 71, or indeed in the range 10% to 80% less than the speed of the drive roller 71, and the second forming roller 73 typically possesses a tangential speed that is greater than that of the drive roller 71, e.g. in the range 5% to 200% greater than that of the drive roller 71, or indeed in the range 10% to 80% greater than that of the drive roller 71.
Furthermore, each of the forming rollers 72 and 73 is typically maintained at a predetermined temperature as a function of the molding material, e.g. in the range 75° C. to 165° C. or more particularly substantially equal to 120° C. for a tape made of polypropylene, while the drive roller 71 is maintained at ambient temperature or at a temperature that is not regulated, or at a temperature that is lower than the heat deflection temperature, e.g. lower than 65° C.
The drive speed and temperature parameters serve to ensure that the heads 53 of the preforms adhere to and/or rub against and/or slide over the forming rollers 72 and 73, thereby giving rise to their deformation.
Upstream from the forming roller 72, the preform under consideration is the same as that described above with reference to
Thereafter,
As can be seen in this figure, in this example the forming roller 72 has deformed the face of the preform at the front of the preform relative to its travel direction.
This deformation gives rise to a rib being formed that extends in a direction that is substantially transverse relative to the longitudinal direction of the tape 100.
The deformation action exerted by the forming roller 72 folds over a portion of the head 53 of the preform corresponding to the face of the preform in the travel direction, however this deformation action leads to flattening of the portions of the head of the preform 53 extending in the transverse direction relative to the travel direction, thereby forming fins extending on either side of the stem 52 in the direction extending transversely to the travel direction of the tape 100. These fins define catch portions 54 of the head 53, extending radially beyond the stem 52 of the preform from the top end 522 of the stem 52.
The deformation performed by the forming roller 72 forms a first rib 81 extending at least in part over the catch portions 54.
More generally, the deformation performed by the forming roller 72 leads to a catch portion 54 being formed together with a rib extending at least in part over the catch portion 54. The rib as formed in this way extends over the top face of the head 53, thereby providing the head 53 with mechanical reinforcement.
When the head 53 has a plurality of catch portions 54, the forming can then give rise to a single rib being formed that extends continuously between the catch portions 54, or to a plurality of disjoint ribs, each extending at least in part over one or more of the catch portions 54.
After this first deformation by the forming roller 72, second deformation may be performed by the forming roller 73.
The temperature and speed of rotation parameters of the forming roller 73 give rise to adhesion of the material of the head 53 of the preform, which serves to stand up a portion of the head 53 projecting from the stem 52.
It should be observed in particular that relative to the tape 100, the forming roller 73 has a direction of rotation that is identical to that of the above-described forming roller 72, and that it possesses a tangential speed that is greater than the tangential speed of the drive roller 71.
As a result of these direction and speed of rotation characteristics, the forming roller 73 deforms the head 53 of the preform in such a manner as to entrain the material of the head 53 towards the front of the preform (relative to its travel direction).
As a result, the forming roller 72 performs first deformation of the preform tending to take material from the front of the preform towards the central portion of the head 53, whereas the forming roller 73 performs second deformation of the preform tending to take material towards the front of the preform.
The previously-formed first rib 81 is thus taken back towards the front of the preform, and it extends beyond the stem 52 of the preform. The first rib as modified in this way is given the reference 81′ in the figures. For reasons of readability, the text refers throughout to the first rib with the reference 81.
A substantially transverse second rib 82 is formed, likewise extending between two transverse ends of the hook, in this example formed by the catch portions 54.
As can be seen in
Each of these two ribs 81 and 82 extends between two opposite ends of the hook in the transverse direction, i.e. between the two catch portions 54 in the example shown.
With reference to the drive direction of the tape through the installation, the hooks define a front face and a rear face. The first rib 81 extends substantially along the front faces of the catch portions 54, while the second rib 82 extends substantially along the rear faces of the catch portions 54. The catch portions 54 thus typically comprise two distinct ribs extending at least in part over the catch portion in question.
The catch portions 54 and the first and second ribs 81 and 82 thus define transverse ends of the hooks having the same substantially U-shaped shape, with a base that is substantially plane and with the two ribs extending in a direction that is substantially perpendicular.
The ribs 81 and 82 thus provide mechanical reinforcement for the catch portions 54, which portions are configured to cooperate with complementary elements such as other hooks or loops in order to form a retaining system. The term “mechanical reinforcement” is used herein to mean that the hook deforms less under the action of a given force when it has one or more such ribs, than would a similar hook not having such a rib.
The catch portions 54 may extend substantially radially relative to the stem 51, or they may present a free end that slopes towards the base 51, as can be seen for example in
Each rib 81 and/or 82 extends over a fraction only of the head 53. The ribs thus typically extend over only a fraction of the periphery of the head 53. The combined length of the ribs typically lies in the range 5% to 95% of the length of the periphery of the head 53, or more precisely in the range 30% to 70% of the length of the periphery of the head 53. The periphery of the head 53 is considered as being the radial periphery of the head 53 after the step of forming the hooks or while being formed in the molding strip 1.
In this example, at least one of the ribs 81 and 82 typically presents a length that is greater than the diameter of the stem 52, its diameter being measured in a direction that is transverse to the longitudinal direction.
As can be seen in the figures, and more particularly in
Typically, the ribs 81 and 82 are symmetrical about a plane extending in a longitudinal direction of the base 51 and containing a central axis of the stem 52 of the retaining elements.
The hooks as formed in this way typically have a height lying in the range 5 μm to 5000 μm, or indeed in the range 5 μm to 2000 μm, or more particularly in the range 20 μm to 800 μm, or still more particularly in the range 100 μm to 500 μm, with the height being measured in a direction perpendicular to the top face 511 of the base 51.
The head 53 may be heated prior to the forming step so that it is at a temperature lying between the heat deflection temperature of the molding material and the melting temperature of the molding material, and the forming device 7 may include a rotary element at a temperature that is less than the heat deflection temperature of the molding material, for example.
As can be seen in particular in
Another aspect of the device as described relates to the regularity of the tape produced in this way.
Injecting molding material by using the material dispenser means 3 makes it possible to obtain a tape having edges in the longitudinal direction that are substantially straight immediately on making the tape, and without requiring an additional cutting step.
This figure is a diagram of the tape 100 obtained as a result of injecting material into the molding strip 1, the tape thus extending in a longitudinal direction as identified by an axis X-X in
Two edges 102 and 104 are defined for this tape 100, each edge extending along the longitudinal direction, these two edges 102 and 104 defining the two ends of the tape 100 in a transverse direction perpendicular to the longitudinal direction.
The hooks or preforms are generally arranged in the proximity of the edges 102 and 104. The hooks or preforms are typically arranged at a distance D from the edges 102 and 104 lying in the range 2 to 3 times the pitch P of the hooks, typically equal to 2 or 3 times the pitch P of the hooks, the distance D being measured along the transverse direction relative to the longitudinal direction represented by the axis X-X in
As shown in
The lows should be understood as regions of the edges 102 and 104 that are indented towards the inside of the tape 100, while the highs should be understood as being regions of the edges 102 and 104 that bulge towards the outside of the tape 100.
The regularity of the edges 102 and 104 can thus be evaluated using the successive highs and lows.
In section view on a direction transverse to the longitudinal direction, the edges 102 and 104 present portions of rounded shape. More particularly, the rounded shape is oriented laterally towards the outside of the base. This rounded shape is made while forming the base. In other words, this rounded shape is not obtained by cutting.
The apparatus and the method as described above make it possible to obtain edges 102 and 104 of the tape such that for a length L along the longitudinal direction corresponding to three consecutive highs, the maximum offset E between the highs and lows in a direction transverse to the longitudinal direction is less than 3.0 mm, or more precisely less than 2.0 mm, or indeed more precisely less than 1.0 mm, or indeed lying in the range 0.001 mm to 1.0 mm, more particularly in the range 0.001 mm to 0.5 mm, still more particularly in the range 0.001 mm to 0.1 mm.
Such a definition is equally applicable to a length corresponding to three consecutive lows; the maximum offset between the highs and lows in a direction transverse to the longitudinal direction is less than 3.0 mm, or more precisely less than 2.0 mm, or indeed more precisely less than 1.0 mm, or indeed lies in the range 0.001 mm to 1.0 mm, more particularly in the range 0.001 mm to 0.5 mm, still more particularly in the range 0.001 mm to 0.1 mm.
The three consecutive highs or lows lie typically over a distance that is less than the distance corresponding to 15 times the hook pitch, preferably less than a distance of 25 mm.
Obtaining edges 102 and 104 that can thus be said to be “straight” is advantageous in that it makes it possible to avoid a subsequent step of straightening the edges, e.g. by using a cutting step, where such straight edges are perceived by the user as being a sign that the product is of good quality.
Furthermore, the apparatus and the method used make it possible to obtain such edges that are straight without requiring any longitudinal extra thicknesses in the margins of the tape, where such extra thicknesses do not present any functional advantage. The base 51 of the tape 100 may thus be free from any extra thickness extending continuously along its edges, and typically presents a thickness that is substantially constant from one edge to the other. More generally, it can be understood that the base 51 of the tape may be free from any non-functional extra thickness (where the only function would be to improve the regularity of the margins of the tape), which is advantageous in production terms in so far as extra thicknesses would lead to overconsumption of material and would increase the length of time the molds are occupied.
As can be understood from the above description, the straight edges are obtained by injecting the molding material via the material dispenser means 3. The subsequent steps of unmolding and of forming conserve the straight edges as described above, in so far as the steps do not involve applying forces to the edges of the base 51 of the tape 100. The tape 100 as obtained in this way after those various steps thus presents an edge that is straight, as defined above.
Furthermore, when at least two distinct materials are dispensed simultaneously or successively by the material dispenser means 3, the interface between the two materials is then typically made so as to present a straight boundary, as described above with reference to the edges of the base 51 of the tape 100. More precisely, when two materials are dispensed simultaneously or in succession, each material is injected by the material dispenser means 3 in such a manner as to form straight edges at both of the transverse ends of the tape of material formed in this way. Consequently, the junctions between the two materials are junctions between two straight edges as defined above, and thus each of them presents a profile that can be said to be “straight” in accordance with the above definition. By way of example, the dispenser means may comprise two injection or extrusion nozzles.
The above described apparatus and the associated method may also present means and a step for associating a substrate with the tape.
Such association of a substrate with a tape having gripper elements is typically performed by means of an adhesive, or by melting the base or the substrate, as mentioned above.
In order to secure a substrate to the base of the tape, the proposed apparatus may include substrate drive means adapted to feed substrate and to apply the substrate against the bottom face 512 of the base 51 of the tape 100 downstream from the material dispenser means 3.
The apparatus as shown is similar to that described above with reference to
As can be seen in
The substrate 200 is typically a layer of nonwoven material, a plastics film, an elastic film, or a composite film, or indeed an assembly of thermo-consolidated fibers and/or filaments. By way of example the substrate 200 is a sheet of fibers and/or filaments.
In the example shown in
The term “nonwoven” material is used to designate a product obtained as a result of forming a sheet of fibers and/or filaments that have been consolidated. Consolidation may be mechanical, chemical, or thermal, and it gives rise to bonds being present between the fibers and/or the filaments. Such consolidation may be direct, i.e. performed directly between the fibers and/or the filaments, by welding, or it may be indirect, i.e. via an intermediate layer between the fibers and/or the filaments, e.g. a layer of adhesive or a layer of binder. The term “nonwoven” material relates to a structure in the form of a tape or sheet of fibers and/or filaments that are interleaved in a manner that is not uniform, i.e. irregular, or at random. A nonwoven material may have a single-layer structure or a structure made up of multiple layers. A nonwoven material may also be combined with some other material in order to form a laminate. A nonwoven material may be made from various synthetic and/or natural materials. By way of example, natural materials comprise cellulose fibers, such as cotton, jute, flax, and the like, and may also include cellulose fibers that have been reprocessed, such as rayon or viscose. Natural fibers for a nonwoven material may be prepared by using various methods such as carding. By way of example, synthetic materials comprise, but without being limited thereto, synthetic thermoplastic polymers known for forming fibers that include, without being limited thereto, polyolefins, e.g. polyethylene, polypropylene, polybutylene, or the like; polyamides, e.g. polyamide 6, polyamide 6.6, polyamide 10, polyamide 12, and the like; polyesters, e.g. polyethylene terephthalates, polybutylene terephthalates, polylactic acids, and the like, polycarbonates, polystyrenes, thermoplastic elastomers, vinyl polymers, polyurethanes, and mixtures and copolymers thereof. By way of example, the nonwoven material may be a material of the type: Spunbond, Spunmelt, melted carded, SMS, SMMS, SS, SSS, SSMMS, SSMMMS, Air through, etc.
The substrate is not limited to a nonwoven material, and could more generally be a nonwoven material, a woven material, a knitted material, or a combination of a plurality of these materials.
The substrate drive means 9 are configured to feed the apparatus with substrate 200 and to apply the substrate 200 against the bottom face 512 of the base 51 of the tape 100 downstream from the material dispenser means 3.
The substrate drive means 9 are configured in such a manner that this application takes place prior to the base 51 of the tape 100 solidifying. Thus, this application causes at least part of the substrate 200 to penetrate beyond a plane defined by the bottom face 512 of the base 51 of the tape 100. In the figures, reference B designates the point where the base 51 of the tape 100 is put into contact with the substrate 200.
More precisely, the bottom face 512 of the base 51 is substantially plane, and it defines a plane. Applying the substrate against this face causes portions of the substrate 200, e.g. fibers and/or filaments of the layer of nonwoven material when the substrate 200 is a layer of nonwoven material, to penetrate into the base 51, thus passing through the bottom face 512 of the base 51.
In so far as such application takes place before the base 51 of the tape 100 has solidified, there is no need to heat the base 51 of the tape 100 and/or the substrate 200 in order to achieve such bonding.
By way of example, assuming that the base 51 is made of polypropylene, the substrate is typically applied against the bottom face 512 of the base 51 while the bottom face 512 of the base 51 presents a temperature lying between the melting temperature and the Vicat B softening temperature of the material constituting it minus 30° C., or indeed between the melting temperature of the material constituting it and the Vicat A softening temperature of the material constituting it. More particularly, when the base comprises material based on polypropylene, the bottom face 512 of the base 51 presents a temperature lying in the range 75° C. to 150° C., typically about 105° C., this temperature typically being measured by means of an infrared camera or a laser. The Vicat softening temperature is the temperature obtained using one of the methods described in the ISO 306 or the ASTM D 1525 standards while heating at a rate of 50° C. per hour (° C./h) and with a standardised load of 50 newtons (N) for Vicat B and a standardised load of 10 N for Vicat A.
More generally, while the substrate 200 is being applied against the bottom face 512 of the base 51, the bottom face 512 of the base 51 is at a temperature lower than its melting temperature, or more particularly lower than the heat deflection temperature of the material forming the base 51, or indeed substantially equal to ambient temperature (or to a non-regulated temperature), and the temperature of the base 51 results solely from the step of forming the tape 100. With reference to above-defined points A, B, and C, and as can be seen in particular in
The roller 92 is typically configured so as to apply the substrate 200 with pressure against the bottom face 512 of the base 51 so as to facilitate penetration of the substrate 200 to the base 51.
The roller 92 may present patterns or portions in relief on its surface, so as to enhance penetration of the substrate 200 into the base 51.
The substrate 200 may be applied in uniform or non-uniform manner against the bottom face 512 of the substrate 51.
The bonding achieved between the substrate 200 and the base 51 of the tape 100 may be uniform or non-uniform.
When the substrate 200 is a set of thermally consolidated fibers and/or filaments, the bonding with the base 51 is also achieved by a fraction of the fibers and/or filaments of the substrate 200 penetrating into the base.
When the substrate 200 is a set of thermally consolidated fibers and/or filaments, a plastics film, an elastic film, or a composite film, a phenomenon might occur during bonding with the base whereby the tape 100 shrinks during cooling, this shrinking enhancing the bonding area between the substrate and the base of the tape. This shrinking is of no impact on the visual appearance for the final user.
More precisely, it is well known that molded parts present a shrinkage phenomenon during cooling of the material. In the present example, the tape 100 presents portions of different thicknesses as a result of the presence of the retaining elements projecting from the top face 511 of the base 51. Such zones presenting extra thickness lead to phenomena of the material shrinking in register with the stems 52 of the hooks, thus forming zones 530 of material shrinkage in the bottom face 512 of the base 51.
However, in so far as the substrate 200 is applied against the bottom face 512 of the base 51 prior to solidification of the base 51, this shrinkage of material takes place after the substrate has been applied against the bottom face 512 of the base 51.
Pressing the substrate 200 against the bottom face 512 of the base 51 in association with the fact that the base 51 has not yet solidified during this application leads to bonding by molecular diffusion between the substrate 200 and against the bottom face 512 of the base 51. Thus, during shrinkage of the material of the base 51 as it solidifies, as mentioned above, the substrate 200 remains in contact with the bottom face 512 of the base 51, and regions of the film forming the substrate 200 thus continue to fit closely to the shape of the material shrinkage zones in the bottom face 512 of the base 51. These regions of the film forming the substrate 200 thus penetrate beyond the plane defined by the bottom face 512 of the base 51. Thus, the surface area of the film forming the substrate 200 in contact with the bottom face 512 of the base 51 is greater than the projection of the surface area of the film onto a plane defined by the bottom face 512 of the base 51, thus making it possible to increase adhesion between the substrate 200 and the tape 100.
When the substrate 200 is a layer of nonwoven material, the hooks are unmolded easily, even with a nonwoven material presenting a weight of less than 80 g/m2. By way of example, the weight of the nonwoven material may lie in the range 5 g/m2 to 120 g/m2, or indeed in the range 10 g/m2 to 70 g/m2.
When the substrate 200 is a layer of nonwoven material, the apparatus may include a calendering device upstream from the substrate drive means 9, thus making it possible (optionally locally) to perform a calendering step on the layer of nonwoven material prior to applying it against the tape 100.
This technique for bonding the substrate 200 to a tape 100 is advantageous, in particular in that it does not lead to the tape 100 becoming deformed, and thus advantageously makes it possible to conserve the shape of the base 51 as obtained during the injection step, and in particular to conserve the straight edges that can be obtained using the above-described method and apparatus.
This bonding of a substrate to a tape can be applied to a method of forming a tape as described above, or more generally to any other method of forming a tape that includes retaining elements such as hooks.
The various above-described apparatuses and methods may be used independently or in combination.
By way of example, there follows a description with reference to
The tape 100 is similar to the tape as described above, and it comprises a base 51 and hooks extending from the top face 511 of the base 51.
The film of elastic material 310 is extruded simultaneously, successively, or prior to extruding the tape 100 by the material dispenser means 3, thereby defining a bond between the tape 100 and the film 310 at one of their transverse ends. The transition between the elastic film 310 and the base 51 of the tank 100 is thus typically continuous.
Thus, the film of elastic material 310, the base, and the retaining elements of the tape 100 made of plastics material are made integrally and are the result of extrusion.
Numerical reference 320 designates the interface between the film of elastic material 310 and the tape 100.
The term “integrally” is used to mean that the tape and the film are bonded together solely by simultaneous or successive distributions of material, e.g. by simultaneous or successive extrusion operations. In other words, the resulting bonding is achieved solely by intramolecular diffusion from the tape to the elastic film and/or from the elastic film to the tape.
This interface 320 may be made in a plane that is substantially parallel to the longitudinal direction of the product 300, as shown in
When the hooks and the base are made out of the same material, it can be seen that there is continuity of material from the base towards the hooks, and vice versa. In other words, the material forming the hooks and the material forming the base are contiguous.
The elastic film 310 is defined as having a top face 311 and a bottom face 312. In the example shown in the figure, the top face 311 of the elastic film 310 in this example extends the top face 511 of the base 51 of the tape 100. In the example shown in
The assembly formed by the elastic film 310 and by the tape 100 thus constitutes an intermediate layer, presenting a bottom face and a top face.
As can be seen in
The substrate 200 may for example be a nonwoven material, as described above.
The substrate 200 is secured to the intermediate layer by partial encapsulation in said intermediate layer, i.e. by partial encapsulation of the substrate in the base 51 of the tape 100 and in the elastic film 310. This bonding is performed using the method and the apparatus as described above with reference to
The product 300 as shown also has a support layer 330 secured to the top face of the intermediate layer. This support 330 extends over the top face 311 of the elastic film 310, and also at least in part over the top face 511 of the base 51 of the tape 100.
The support layer 330 may be identical in composition to the substrate 200, or it may have a different composition; for example, it may be a layer of nonwoven material, a knit, or a grid.
In the example shown, the support layer 330 is secured on the top face of the intermediate layer by adhesive.
The support layer 330 is then typically secured to the top face of the intermediate layer after securing the substrate 200 to the bottom face of the intermediate layer.
It can readily be understood that securing in this way is merely illustrative, and that any other suitable method may be used for securing the support layer 330 on the top face of the intermediate layer.
By way of example, the support layer 330 may be arranged on the molding strip 1 prior to the material dispensing means 3 dispensing material, such that the plastic and elastic material materials are injected onto the molding strip while the support layer 330 is positioned on the molding strip 1, as mentioned above.
The top face and/or the bottom face of the base 51 of the tape 100 and/or of the elastic film 310 may optionally be smooth (with the exception of the hooks). By way of example they may present elements in relief, e.g. transition elements, hooks that have been eliminated, recesses such as holes or slots, or projections such as spikes, points, domes, and/or pins. These elements in relief may present a height that is smaller than the height of the retaining elements, more particularly less than 40% of the height of retaining elements, in particular less than 25% of the height of the retaining elements. Such elements in relief can be advantageous in certain applications, e.g. in order to define zones of distinct roughness or of different surface appearance providing advantages that may be practical and/or aesthetic.
When the substrate 200 and/or the support layer 330 is a nonwoven material, the substrate 200 and/or the support 330 may be activated prior to being secured to the intermediate layer, as mentioned above.
The term “plastics material” is used to mean a thermoplastic material, more particularly a polyolefin material based on a homopolymer or a copolymer.
By way of example, a plastics material from the following list: linear low density polyethylene (LLDPE), low density polyethylene (LDPE), metallocene polyethylene (m-PE), high-density polyethylene (HDPE), ethylene vinyl acetate (EVA), and polypropylene (PP), having a molecular weight distribution that is monomodal or multimodal (e.g. bimodal), in particular a composition comprising LLDPE and a plastomer, in particular a plastomer based on polyethylene. It is also possible to use polyimide (PA), polylactic acid (PLA), polyhydroxyalkanoates (PHA), polyvinyl alcohols (PVOH), polybutadiene styrene (PBS).
The term “elastic material” is used to mean a material suitable for being stretched under the effect of a stretching force exerted in the lateral direction and then for returning substantially to its initial shape and dimensions after said stretching force has been released. By way of example it may be a material that conserves residual deformation or remanence after elongation and release (where such residual deformation is also referred to as “permanent set” or “set”) that is less than 30%, or indeed less than 20%, e.g. less than 5%, of its initial dimension (prior to elongation) after being lengthened by 100% of its initial dimension, and at ambient temperature (23° C.). Set can be measured as described in patent application EP 1 783 257, the content of which is incorporated by reference, and in particular the paragraphs [0056] to [0062] of the publication EP 1 783 257 A1 which describe in detail an example of measuring set.
As examples of elastic materials, mention may be made of: styrene/isoprene copolymers (SI), styrene/isoprene/styrene (SIS), styrene/butadiene/styrene (SBS), styrene-ethylene/butylene-styrene (SEBS), styrene-ethylene/propylene-styrene (SEPS), or styrene isoprene butadiene (SIBS). It is also possible to take account of mixtures of these elastomers with one another or with non-elastomers that modify certain characteristics other than elasticity. For example, up to 50% by weight, but preferably less than 30% by weight of polymer may be added in order to modify certain characteristics of the base materials (elasticity, high-temperature behavior, processability, resistance to ultraviolet (UV) radiation, . . . ), polyvinyl styrenes, polystyrenes or poly a-methyl styrenes, epoxy polyesters, polyolefins, e.g. polyethylenes or certain ethylene/vinyl acetates, preferably those of high molecular weight.
In particular, the elastic material may be a styrene-isoprene-styrene, e.g. available from the supplier Kraton Polymers, under the name KRATON D (registered trademark), or from the supplier DEXCO POLYMERS LP under the name VECTOR SBC 4211 (registered trademark). It is also possible to use thermoplastic elastomer (TPE) materials in particular a thermoplastic elastomer of polyurethane, in particular PELLETHANE (registered trademark) 2102-75A from the supplier The Dow Chemical Company. It is also possible to use a styrene-butadiene-styrene, in particular KRATON D-2122 (registered trademark) from the supplier Kraton Polymers, or VECTOR SBC 4461 (registered trademark) from the supplier Dexco Polymers LP. It is also possible to use a styrene-ethylene/butylene, in particular KRATON G-2832 (registered trademark) from the supplier Kraton Polymers, or a sequenced styrene-ethylene-butylene-styrene copolymer (SEBS), in particular KRATON (registered trademark) G2703. It is also possible to use a copolymer of isooctyl acrylate and of acrylic acid with a monomer ratio of 90/10. It is also possible to use a sequenced polyimide polyester copolymer PEBAX (registered trademark) 2533 from the supplier Arkema.
Other possible materials are polyolefins polymers, mainly copolymers of ethylene and/or propylene having the characteristics of elastomers, in particular obtained by metallocene catalysis, such as VISTAMAXX VM-1120 (registered trademark), available from the supplier Exxon Mobil Chemical or indeed rubber-filled polymers such as for example Santoprene filled with EPDM.
It is also possible to use materials to enhance bonding between the plastics material and the elastic material. In a variant embodiment, it is possible to envisage that each of the cavities in the molding strip includes a stem that extends between the top face and the bottom face of the molding strip, from one of its faces to the other.
Various systems and methods compatible with the present disclosure are described in patent applications FR 16 53866, FR 16 53870, FR 16 53872, FR 16 53873, FR 16 53888, FR 16 53894, and FR 16 53897, which are incorporated in full by reference in this description.
Number | Date | Country | Kind |
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1653866 | Apr 2016 | FR | national |
1653870 | Apr 2016 | FR | national |
1653872 | Apr 2016 | FR | national |
1653873 | Apr 2016 | FR | national |
1653888 | Apr 2016 | FR | national |
1653894 | Apr 2016 | FR | national |
1653897 | Apr 2016 | FR | national |
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PCT/FR2017/051012 | 4/28/2017 | WO |
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WO2017/187099 | 11/2/2017 | WO | A |
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