This invention relates to touch fastener products as mold inserts, such as in the molding of seat foam buns and the like.
Seats for cars and light trucks have been formed by molding a foam bun that will serve as the seat cushion, and then attaching a pre-stitched fabric cover to the foam bun. Often, the fabric cover is attached to the foam bun by insert molding touch fastener products into the outer surface of the foam bun and attaching cooperating touch fastener products to an inner surface of the fabric cover. Generally, the fastener products are attached to the fabric cover along the seams where the cover is stitched together and held in place by the seam stitching. The touch fastener products allow the seat manufacturer to rapidly and semi-permanently attach the fabric cover to the foam bun by pulling the fabric cover over the foam bun and pressing the opposed touch fastener products on the foam bun and fabric cover together.
In general, the touch fastener products can be secured to the seat foam bun during a molding process, such as by holding the fastener products magnetically against a side of the mold cavity in which the foam bun is molded. During this molding process, care must be taken to avoid fouling of the fastener elements with the liquid foamable composition used to form the seat. Fouling can occur if the liquid foaming composition leaks between the edges of the base of the touch fastener product and the mold surface into the space between the fastener elements (e.g., hooks).
In one aspect, a touch fastener product includes an elongated base having multiple segments connected by articulable joints. Each segment has upper and lower surfaces and a plurality of touch fastener elements extending from the lower surface of the base. A flexible barrier extends across at least one articulable joint between adjacent base segments.
In another aspect, a touch fastener includes an elongated base having upper and lower surfaces and a plurality of touch fastener elements extending from the lower surface of the base. The base defines a series of spaced apart pairs of opposite notches in its longitudinal edges, forming respective articulable base joints. Adjacent pairs of notches define respective base segments between them. The notches are each sized with respect to an overall width of the base such that, when one of the articulable joints is flexed to close one of its corresponding notches, the other of its corresponding notches opens only to a longitudinal gap dimension less than about 0.5 millimeter. The fastener may also include a flexible barrier, such as a film, extending across at least one articulable joint between adjacent base segments.
The articulable joints may be spaced closer together along some regions of the base than along other regions of the base to allow greater curvature of the touch fastener. Generally, the articulable joints may have a longitudinal joint spacing of between about 5 and 50 millimeters.
The fastener may also include a magnetically attractable material disposed along a center region of the upper surface of the base. The magnetically attractable material may be discontinuous over the length of the touch fastener. In one example, the width of the magnetically attractable material is less than about 25% of the width of the base. In another example, the width of the magnetically attractive material is less than about 10% of the width of the base. In yet another example, the width of the magnetically attractable material is less than about 5% of the width of the base.
The magnetically attractive material may comprise iron particles, which can be fused together to form a cylindrical shape having a diameter between about 0.4 mm and 3.5 mm. The cylindrical shape of fused iron particles extends across the length of the base.
In one example, the magnetically attractable material is a metallic wire which may extend across at least one of the articulable joints. The wire is secured to the upper surface of the base by resin, in one example. In another example, the magnetically attractable material is secured to the upper surface of at least one base segment in at least one location along the base segment, allowing the magnetically attractable material to move at other locations.
The barrier may be a film which may be secured by an adhesive, such as a polyurethane hot melt. The film may be a polyamide or polyurethane as well. The film has a nominal thickness of less than about 0.002 inch. In another example, the film has a nominal thickness of less than about 0.010 inch. In some examples, the film has a flexural rigidity of about 1800 mg-cm; and a tensile stiffness of between about 1000 and about 3000 mg-cm.
In some examples, the barrier is wider than the base, such that the barrier extends beyond longitudinal edges of the base. In one example, the barrier extends beyond longitudinal edges of the base at the joints. The barrier material may also be more flexible than the base and may comprise an elastomeric material.
The fastener base may define a pair of first and second notches in opposite longitudinal edges of the base at the articulable joint to allow the approximation of a curve in the base. The notches extend completely through the base. In some examples, each notch defines a longitudinal gap dimension of less than about 0.25 and a notch angle of between about 2 and 90 degrees between opposing base surfaces. In one example, the base edges in the first and second notches are bent in opposing directions to allow the base edges to overlap when the joint is bent.
The base may also define a slit extending through the base from a longitudinal edge thereof at the articulable joint. In one example, the barrier defines a slit in through a longitudinal edge of the flexible barrier and aligned with one of the notches at the articulable joint. The slit can extend across a majority of a lateral width of the base. In another example, the base defines a notch extending from a longitudinal edge of the base opposite the slit.
The fastener base may include multiple discrete barrier segments, such that each barrier segment extends across at least one respective articulable joint. Each barrier segment may be secured to longitudinal center portions of two adjoining base segments; to only one of the two adjacent base segments defining its respective articulable joint; or both.
A flexible compressible gasket may be secured to the lower surface of the base. The gasket extends across at least one articulable joint to impede foam intrusion during a molding process. In one example, the barrier material is a flexible compressible gasket.
The adjacent base segments of the fastener can also be joined at rotatable pivots at the articulable joints. In one example, adjacent base segments are joined at the articulable joints by a link at two rotatable pivots. Similarly, adjacent base segments can also be joined at articulable joints by a single rotatable pivot.
A method of making a touch fastener includes continuously introducing a flexible substrate to a gap formed along a peripheral surface of a rotating mold roll. Another step includes introducing molten resin to the gap between the substrate and the peripheral surface of the mold roll, such that the resin at least partially fills an array of cavities defined in the rotating mold roll to form resin stems while a base of resin interconnecting the stems is laminated to the substrate on the peripheral surface of the roll. Additional steps include forming engageable heads on the stems and forming longitudinally spaced apart discontinuities in the base to provide articulable joints between adjacent base segments, across which the substrate extends.
The discontinuities may be formed by introducing the resin to the gap in longitudinally spaced apart quantities defining gaps between them. In another instance, the discontinuities are formed after the resin base is stripped from the mold roll. The heads are formed by molding the heads with the stems in the cavities.
The step of forming articulable joints my also include forming a pair of first and second notches in opposite longitudinal edges of the base at the articulable joint. The notches may extend completely through the base. In some examples, the notches each define a longitudinal gap dimension of less than about 0.25 inches and include a notch angle of between about 2 and 90 degrees between opposing base surfaces.
The method may also include a step of forming a slit extending through the base from a longitudinal edge thereof at the articulable joint. The slit may extend across a majority of a lateral width of the base. A notch may also be formed that extends from a longitudinal edge of the base opposite the slit.
During the step of forming the articulable joints, the joints may be formed closer together along some regions of the base than along other regions of the base to provide the ability to approximate greater curves. The joints may also be formed with a longitudinal joint spacing of between about 5 and 50 millimeters.
The method may include an additional step of securing a flexible barrier material, such as a film, to the base, such that the barrier material extends across at least one articulable joint between adjacent base segments. The barrier may define or have formed in it a slit in through a longitudinal edge of the flexible barrier and aligned with one of the notches at the articulable joint. In one example, the barrier defines two slits through opposite longitudinal edges of the barrier and aligned with the first and second notches of the base. The barrier material is wider than the base, such that the barrier material extends beyond longitudinal edges of the base. The barrier material may also be more flexible than the base and may comprise an elastomeric material.
The method may include an additional step of securing multiple discrete barrier segments, such that each barrier segment extends across at least one respective articulable joint. Each barrier segment may be secured to longitudinal center portions of two adjoining base segments; to only one of the two adjacent base segments defining its respective articulable joint; or both.
Additionally, the method may include the step of disposing a magnetically attractable material, such as a metallic wire, along a center region of an upper surface of the base. The magnetically attractable material extends across at least one of the articulable joints and may be severed at the joints to provide greater freedom of motion. The magnetically attractable material is secured to the upper surface of at least one base segment in at least one location along the base segment, allowing the magnetically attractable material to move at other locations. Segments of magnetically attractable material may be disposed along a center region of an upper surface of the base, between the articulable joints.
Another step includes disposing a fabric patch over at least one articulable joint.
Yet another step includes securing a compressible gasket to a lower surface of the base. The gasket extends across at least one articulable joint to impede foam intrusion during a molding process.
The method may include an additional step of forming rotatable pivots to join adjacent base segments at the articulable joints.
A method of forming a seat foam bun includes providing a mold cavity having a shape corresponding to the shape of the seat foam bun. The mold cavity defines a trench. Another step includes providing a touch fastener that includes an elongated base having multiple segments connected by articulable joints. Each segment has upper and lower surfaces and a plurality of touch fastener elements extending from the lower surface of the base. A flexible barrier extends across at least one articulable joint between adjacent base segments. Another step includes positioning the touch fastener along the trench with the flexible barrier in contact with a surface of the mold cavity. In yet another step, a foamable resin is delivered into the mold cavity to form a seat foam bun, while the flexible barrier resists intrusion of foamable resin into the plurality of touch fastener elements at the joints.
The various implementations and examples disclosed herein can provide an easy means of configuring a touch fastener product to follow a curved path in a molding process. Current methods employ short parts of touch fastener product placed individually to approximate a curve. Consequently, there are considerable areas along the curve with no available fastener elements, such as between parts and at end gaskets. The examples of notched touch fastener products disclosed herein may provide more continuous regions of available fastener elements. Furthermore, the use of barriers, as shown in the examples, may reduce foam intrusion during a molding process, thus increasing the amount of available fastener elements.
The details of one or more implementations of the invention are set forth in the accompanying drawings and the description below. Other features, objects, and advantages of the invention will be apparent from the description and drawings, and from the claims.
Like reference symbols in the various drawings indicate like elements.
Referring to
In some instances, the touch fastener product can be laminated to a mesh or scrim material. The scrim material can provide improved dimensional stability. Moreover, the scrim material can be magnetic (or attracted to magnets) (e.g., a ferrous-impregnated non-woven material), thus providing a magnetically attractable material as discussed above. Suitable examples of laminates are described in U.S. Pat. No. 5,518,795 to Kennedy et al. entitled LAMINATED HOOK FASTENER, the entire disclosure of which is incorporated herein by reference.
In the examples shown in
In another configuration, a magnetically attractable material 60B includes an extruded longitudinal strand of plastic resin (e.g. Polypropylene or Polyetheylene) combined with iron powder (particles can range in size from 50-200 μm). Iron powder is compounded with a plastic resin such as polypropylene or polyethylene. The compounded resin is then converted into pellet form, which is fed to an extrusion process, where the pellets are melted and formed into any number of shapes.
Referring to
In some implementations, a touch fastener 10 includes an elongated base 20 having upper and lower surfaces 22 and 24 and a plurality of touch fastener elements 100 extending from the lower surface 24 of the base 20. The base 20 defines a series of spaced apart pairs of opposite notches 50 in its longitudinal edges and forming respective articulable base joints 40. Adjacent pairs of notches 40 define respective base segments 25 between them. The notches 50 are each sized with respect to an overall width of the base 20 such that, when one of the articulable joints 40 is flexed to close one of its corresponding notches 50, the other of its corresponding notches 50 opens only to a longitudinal gap dimension less than about 0.5 millimeters. A gap of about 0.5 millimeter will generally not allow significant foam intrusion during a molding process such that it hinders hook performance. Nevertheless, larger gaps that do allow foam intrusion may still be employed because the amount of hook covered with foam would be small compared to the discontinued hook conventionally seen in foam pads that have short hook parts spaced apart to approximate a curve.
The barrier 30 is generally wider than the base 20, such that the barrier 30 generally extends beyond the longitudinal edges of the base 20 and, in one implementation, extends beyond the longitudinal edges of base 20 at joints 40, as shown in
In one example, the base 20 has a width of about 8 mm and is constructed from a resin, such as polyester, polypropylene, or nylon, and has a nominal thickness of about 0.010 inch. The array of fastener elements 100 extends over a longitudinal central region of a lower face 24 of the base 20 that is about 4 mm wide. In the same example, the film barrier 30 is about 12 mm wide, extending laterally and longitudinally beyond the base 20. The selvedge that seals on the tool is comprised of the very flexible edges of the barrier 30 and at the rigid selvedge of the base 20. The fastener elements 100 are hooks positioned in alternating rows of hooks facing in opposing directions. As shown in
The film 30 may be a polyamide film secured by a moisture cure polyurethane adhesive. The film 30 has a nominal thickness of less than about 0.020 inch. In one example, the film has a nominal thickness of about 0.002 inch. In other examples the film has a nominal thickness of less than about 0.010 inch. The film has a flexural rigidity of about 1800 mg-cm and a tensile stiffness of between about 1000 and about 3000 mg-cm.
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As described earlier, the flexible barrier 30 may be extended across at least one articulable joint 40 between adjacent base segments 25.
A method of making a touch fastener 10 with an example apparatus 200, as illustrated in
In example apparatus 200, the gap 220 is a nip defined between the mold roll 230 and a counter-rotating pressure roll 232. Referring to
Pressure applied in the nip causes the molten resin to enter mold cavities 256, defined by the tool rings 234, which are configured to mold the molten resin into desired shapes (e.g. hooks with loop-engageable heads). For purposes of illustration, the size of the mold cavities is exaggerated and the number of mold cavities and associated tool and spacer rings is reduced in all of the Figures showing mold cavities. All of the mold rolls are assembled of tool and spacer rings although individual rings are only shown in
The mold roll 230 is temperature controlled to solidify the molten resin as a base 20 and molded hooks 100 extending from the base. The hooks 100, resin base 20, and attached substrate 30 are stripped from the mold roll 230 by tension applied at a stripping roll 252. The resulting fastener product 10 may be gathered on a storage roll.
The method of making the touch fastener 10 may also include forming a slit 55 that extends through the base 20 from a longitudinal edge thereof at an articulable joint 40. The slits 55 may be formed by passing touch fastener 10 through a rotary or stationary die cutter. The slit 55 may extend across a majority of a lateral width of the base 20. Another step may include forming a notch 50 that extends from a longitudinal edge of the base 20 opposite the slit 55.
In one example, the method of making touch fastener 10 includes forming articulable joints 40 closer together along some regions of the base 20 than along other regions of the base 20. In one example, the articulable joints 40 are formed with a longitudinal joint spacing of between about 5 and 50 millimeters.
The method of making touch fastener 10 may also include securing a flexible barrier material 30 to the base 20, such that the barrier 30 extends across at least one articulable joint 40 between adjacent base segments 25. Additionally, a slit 55 may be formed in through a longitudinal edge of the flexible barrier 32 and aligned with one of the notches 50 at the articulable joint 40. For example, two slits may be formed through opposite longitudinal edges of the barrier 30 and aligned with first and second notches 50 of the base 20.
In another implementation, the method of making the touch fastener 10 may include securing multiple discrete barrier segments 35 to the base 20, where each barrier segment extends across at least one respective articulable joint 40. One step may include dispensing hot melt adhesive from a nozzle onto the base 20, followed by dispensing barrier segments 35 from a label dispenser onto and being secured to base 20. Each barrier segment 35 may be secured to longitudinal center portions of two adjoining base segments 25. In another example, each barrier segment 35 may be secured to only one of the two adjacent base segments 25 defining its respective articulable joint 40. Furthermore, the step may include securing each barrier segment 35 to longitudinal center portions of two adjoining base segments 25 as well as to only one of the two adjacent base segments 25 defining its respective articulable joint 40. Another step may include disposing a fabric patch over at least one articulable joint.
The method of making touch fastener 10 may also include the step of disposing a magnetically attractable material 60, such as a steel wire, along a center region of an upper surface of the base 20. The magnetically attractable material 60 is positioned so as to extend across at least one of the articulable joints 40. In addition, the magnetically attractable material 60 may be severed at the articulable joint 40 to allow greater movement about the joint 40. The magnetically attractable material 60 can be secured to the upper surface 22 of the base 20 by resin 65. In another example, the magnetically attractable material 60 is secured to the upper surface 22 of at least one base segment 25 in at least one location along the base segment, allowing the magnetically attractable material 60 to move at other locations.
Another step may include securing a flexible compressible gasket 90 to a lower surface of the base 20. The gasket 90 may be positioned so as to extend across at least one articulable joint 40 to impede foam intrusion during a molding process.
In another implementation, the method of making the touch fastener 10 may include the step of forming rotatable pivots 120 to join adjacent base segments 25 at the articulable joints 40. In one example, adjacent base segments 25 are joined to a link 130 at rotatable pivots 120.
Referring to
In some instances, as depicted in
In the examples illustrated in
The touch fasteners 10 are molded into a seat foam bun 500, for example as depicted in
Other examples of forming a touch fastener for use as a mold insert are described in U.S. patent application Ser. No. 10/791,204 to Line et al. entitled TOUCH FASTENER PRODUCTS; U.S. Provisional Patent Application No. 60/829,761 to Janzen et al. entitled FASTENER SYSTEMS FOR SEAT CUSHIONS; and U.S. Provisional Patent Application No. 60/829,822 to Line et al. entitled TOUCH FASTENER PRODUCTS, the entire disclosures of which are hereby incorporated herein by reference.
A number of implementations of the invention have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the invention. For example, the discrete barrier segments 35 are depicted in
This U.S. patent application claims priority under 35 U.S.C. §119(e) to U.S. Provisional Application 60/829,836, filed on Oct. 17, 2006 and U.S. Provisional Application 60/829,996, filed on Oct. 18, 2006. The disclosures of the aforementioned prior applications are hereby incorporated by reference in their entireties and are therefore considered part of the disclosure of this application.
Number | Name | Date | Kind |
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3717908 | Perina | Feb 1973 | A |
5518795 | Kennedy et al. | May 1996 | A |
6656563 | Leach et al. | Dec 2003 | B1 |
6803010 | Leach et al. | Oct 2004 | B2 |
20040108620 | Leach et al. | Jun 2004 | A1 |
20050196599 | Line et al. | Sep 2005 | A1 |
Number | Date | Country | |
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20080092348 A1 | Apr 2008 | US |
Number | Date | Country | |
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60829836 | Oct 2006 | US | |
60829996 | Oct 2006 | US |