Conventional articles of athletic footwear such as shoes may include an upper and a sole assembly. The upper may provide a covering to receive and securely position a foot with respect to the sole assembly. In addition, the upper may have a configuration that protects the foot and provides ventilation, thereby cooling the foot and removing perspiration. Footwear uppers may be formed of various materials, including canvas, for example. The sole assembly may be secured to a lower portion of the upper and may, when the footwear is worn, be generally positioned between the ground and the wearer's foot. In addition to attenuating ground reaction forces, the sole assembly may provide traction, control foot motions (e.g., by resisting over pronation), and impart stability, for example. An insole may be located within the upper and adjacent to a plantar (i.e., lower) surface of the foot to enhance footwear comfort, and is typically a thin, compressible member. Various materials may be used in footwear uppers and in sole structures.
The figures referred to above, which are not drawn necessarily to scale, are merely conceptual in nature and intended to show one or more features of one or more examples of the disclosure. Some features shown in the drawings may be enlarged and/or distorted, relative to other features, to facilitate explanation and understanding. The same reference numbers are used in the drawings for similar or identical components and features. Additional examples of articles (e.g., articles of footwear) according to the disclosure may have some or all of the features shown in the drawings, and/or may include additional features. The configurations and components of such examples may be determined, in part, by the intended application and environment in which they are to be used.
Products that are successful in the marketplace, particularly consumer products, may have both functional and aesthetic characteristics. Over time, however, the aesthetic characteristics of a product may take on an importance that may interfere with a manufacturer's ability to improve the functional characteristics of that product. In particular, consumers of a product may become accustomed to one or more aspects of that product's appearance as that product remains on the market for longer and longer periods of time. Consumers may associate that appearance with a product or source, and/or may wish to purchase that product based on such association. Consumers may also or alternatively simply find those aesthetic features of the product to be visually appealing. If well-known aesthetic features of a product are changed, consumers may refuse to continue purchasing that product. As a result, a manufacturer of that product may have difficulty incorporating a functional improvement if a product change associated with that functional improvement will interfere with an established appearance that buyers have come to associate with the product.
These problems may occur in connection with footwear. For example, Converse Chuck Taylor All Star® footwear is a line of products that have been continuously on sale for many years, and that have numerous appearance features that have become iconic. Consumers expect—and demand—these appearance features. If these appearance features are changed too much, consumers may simply buy some other shoe.
One such appearance feature of Converse Chuck Taylor All Star® footwear relates to stitching. Traditionally, certain types of Converse Chuck Taylor All Star® footwear have included uppers formed from canvas. Those canvas uppers include parallel lines of stitching along the upper, proximate the collar and the throat of the upper, that helps secure an outer panel of the upper to a lining of the upper. This stitching is, along with other appearance features, an important component of the overall look of the product. If the appearance of this stitching were to change, the shoe would simply not look the same.
The parallel stitching lines in traditionally-manufactured Converse Chuck Taylor All Star® footwear are formed using a double needle straight lock stitch. That type of stitch does not elongate or stretch. Because the canvas used for uppers of those traditionally-manufactured products also does not stretch, this has not previously been a concern. However, stretchable canvas materials that have an appearance similar to the non-stretchable canvas used for traditionally-manufactured products are available. Incorporating such stretchable canvas into uppers of Converse Chuck Taylor All Star® footwear would offer multiple functional advantages such as improved fit and greater wearer comfort. However, the benefits of replacing the canvas used in those uppers would be reduced (if not lost) if straight lock stitches are used for the parallel stitching lines. Because straight lock stitching does not stretch, use of straight lock stitching would drastically reduce (if not eliminate) the stretchability of the stretch canvas along that straight lock stitching (e.g., along edges of the ankle collar and throat).
Other stitch types do allow elongation. However, many of those stitch types have a very different appearance, and as mentioned, many devoted consumers of the Chuck Taylor All Star® shoe demand fidelity to its traditional appearance, even in the details. One stitch type that allows elongation, and that also has an appearance similar to double needle straight lock stitching on one side, is a double needle cover stitch. As explained in further detail below, a double needle cover stitch may be formed using two needle threads and a loop thread. The two needle threads may be arranged as parallel lines of regularly spaced loops that penetrate joined materials, and that have an outward appearance similar to straight lock stitching. The loop thread, which is located on an opposite side of the material, interloops and interlaces the loops of the needle threads in a pattern that allows the stitch to elongate along the length of the stitch.
The double needle cover stitch is not known to have previously been used in connection with shoes. Indeed, and despite inquiries among various high-volume footwear manufacturers, the inventors were unable to find a footwear manufacturer having equipment in its factory that was even capable of performing cover stitching in connection with a shoe upper. Ultimately, it was necessary to work with stitching machine vendors to obtain equipment that could produce double needle cover stitching. A footwear manufacturer then had to integrate that equipment into a process for making uppers.
Double needle cover stitching has been used in garment applications such as hems around arm or leg openings. Forces on such a hem are different than those found in the ankle and/or throat of an upper. A garment hem line may be tensioned somewhat (e.g., around a sleeve opening of a tightly fitting t-shirt) and may be subject to some abrasion against a wearer's skin or other garment. In a shoe, however, such forces would normally be greater in magnitude and/or sustained over a much longer period. For example, a shoe wearer may secure a shoe by tightly cinching laces, thereby imparting tension along the edges of the upper in the ankle opening and/or throat region. As the shoe wearer walks, runs, etc., the tension along the ankle collar and/or throat regions would be increased. Users or manufacturers have sought to provide elastic tensioning to footwear by replacing standard laces with laces that have elastic properties, enabling limited lace elongation. However, the stitching of shoe uppers, particularly around the collars, has typically been selected for secure, durable, immobile connection of shoe materials.
The upper 14 may be comprise a stretchable canvas material. Stretchable canvas used for the upper 14 may be formed from various materials and may have various properties. For example, an outer layer of the upper 14 may comprise an example stretchable canvas that is a stretchable canvas material having a fiber content of approximately 73% cotton, approximately 15% nylon, and approximately 12% spandex, and a weight of approximately 451.5 grams per square meter (g/m2). The example stretchable canvas may be a plain weave in which weft and warp threads cross at right angles, and which may have an appearance that emulates traditional non-stretch canvas materials used in previous shoes. The example stretchable canvas may include yarns or fibers extending in weft and warp directions and may have a weft direction stretchability that is greater than a warp direction stretchability.
Stretchability of material in a particular direction may be the degree to which that material is elastically elongatable in that direction. Stretchability (or elastic elongatability) in a particular direction may be quantified as a percentage of an original length (in that direction) by which a material will extend without breaking when tension is applied, and from which extension the material will return to the original length after tension is released. The example stretchable canvas may have a weft direction stretchability percentage of between 120% and 170% and a warp direction stretchability percentage between 20% and 35%. The warp direction stretchability percentage may also or alternatively be expressed as a percentage of the weft direction stretchability percentage (e.g., if weft direction stretchability percentage is X % and warp direction stretchability percentage is Y %, warp direction stretchability percentage may be Y/X % of the weft direction stretchability percentage). The example stretchable canvas may have a warp direction stretchability percentage that is between 12% and 29% of the weft direction stretchability percentage. As another example, a stretchable canvas may have a weft direction stretchability percentage up to 138% and/or a warp direction stretchability percentage between 5% and 10%.
The term “approximately” means close to, or about a particular value, within the constraints of sensible commercial engineering objectives, costs, manufacturing tolerances, and capabilities in the field of footwear manufacturing and use. The term “substantially” means mostly, or almost the same as, within the constraints of sensible commercial engineering objectives, costs, manufacturing tolerances, and capabilities in the field of footwear manufacturing and use.
Stretchable canvas material may be elastically elongatable so as to stretch from an at rest condition to a fully stretched condition and then restore itself to the at rest condition. Including stretchable canvas material in the upper 14 may improve flexibility, comfort, and easy on/off wearability of the shoe 10. For example, when the lace 22 is threaded through all of the eyelets 18 and tied, a wearer may still be able to don or remove the footwear 10 without untying the lace 22.
The upper 14 may include stitching 24 to secure layers of the upper 14 to one another. In particular, and as described in more detail in connection with
Examples of materials that may be used for the liner material include stretch canvas and stretch knits. The liner material may be more stretchable in one direction than another, or may have a stretchability that is approximately the same in all directions. If a liner material has a direction of maximum stretchability, the panel 32 and the panel 31 may be cut from larger sheets of materials such that, when the panels 31 and 32 are aligned as shown in
A top edge 33 of the panel 31 and a top edge 34 of the panel 32 may be sewn together, using stitching 35, to create a first partial shell 38. The stitching 35 may, for example, comprise overlock stitching. Additional details of the stitching 35 are shown in
The stitching 24 may then be applied to the second partial shell 42 to create a third partial shell 44. The third partial shell 44 shown in
As indicated above, the stitching 35 may be an overlock stitch (also known as an over edge stitch). Although a three-thread overlock stitch (e.g., an ASTM D-6193 type 504 stitch) is shown in the example of
The stitching 35 comprises three threads: a needle thread 51 and two looper threads 54 and 55. The needle thread 51 may extend over the surface the panel 31 along a path parallel to the edges 33 and 34 of the panels 31 and 32, with loops of the thread 52 penetrating the panels 31 and 32 at regular intervals. The threads 54 and 55 may extend over the edges 33 and 34. In the completed upper 14 the structure of the stitching 35, and of the portions of the panels 31 and 32 extending from the thread 51 to the edges 33 and 34, may be substantially the same throughout as is shown in
The stitching 24 comprises three threads: two needles threads 61 and 62 and one looper thread 63. The needle threads 61 and 62 may extend over the surface of the panel 31 in parallel paths, with loops of the threads 61 and 62 penetrating the panels 31 and 32 at regular intervals. As partially seen in
The stitching 35 and the stitching 24 are extensible and allow portions of the panels 31 and 32 secured by that stitching to stretch. This allows use of stretch canvas material in the upper 14 without unduly limiting the stretchability of that material in regions having the stitching 24 or the stitching 35. Moreover, the stitching 24 may have an appearance, on one side of the stitch, that is similar to that of the stitch type traditionally used in some types of shoes. In particular, each of the needle threads 61 and 62 appears similar to one side of a line of straight lock stitching. This allows a shoe to maintain an appearance, associated with shoes made without stretch canvas or other stretch materials, that consumer may demand. The looper thread 63 may be exposed on an interior surface of the upper 14, as can be seen in
Although examples of materials, stitch types and position, and other configurations are provided above, other materials, stitch types and/or positions, and/or other configurations may also or alternatively be used. For example, different types of stretch canvas may be used. Such other stretch canvas materials may have different amounts of stretchability in the weft direction. For example, prior to attachment to a liner or other material, a stretch canvas may have a weft direction stretchability of at least 25%, at least 50%, at least 75%, at least 100%, at least 150%, or more than 150%. A stretch canvas material may be stretchable in the warp direction (e.g., may have a stretchability of any of the previously-mentioned percentages) instead of the weft direction, and/or may have different weights, different combinations of fibers, and/or different weaves. Instead of being stretchable in the weft direction (or warp direction) and not stretchable in the warp (or weft) direction, stretch canvas used for an upper may have a first degree of stretchability in one of the weft or warp directions, and a second degree of stretchability, less than the first degree, in the other of the weft or warp directions. Stretch canvas may be arranged in an upper so that directions of maximum stretch and of no (or less than maximum) stretch are different from that shown as directions S and NS in
In step 102, stitching (e.g., the stitching 35) may be applied to edges of the panels. That stitching may be applied, for example, to secure those panel edges together. In step 104, the panels secured by the stitching of step 102 may be turned right side out. After turning the panels right side out, the stitched edges may be hidden between the remainder of the two panels.
In step 106, stitching (e.g., the stitching 24) may be applied to the panels that were turned right side out in step 104. This stitching may further secure the panels together. The stitching of step 106 may be in portions of the panels that are adjacent or otherwise proximate edges of the panels that will become edges of an ankle collar (e.g., the ankle collar 16) and/or a throat (e.g., the throat 17) in a completed upper. The stitching of step 106 may be applied so that one or more needle threads are on a surface that will become an exterior surface of the upper and so that one or more looper threads are on a surface that will become an interior surface of the upper.
In step 108, additional fabrication operations for the upper may be performed. Lace eyelets and/or ventilation holes may be added. A toe piece and/or a tongue may be attached. An Achilles region reinforcing strip may be attached. A strobel or other lasting element may be attached. In step 110, the upper from step 108 may be attached to a sole structure.
One or more of the steps of
For the avoidance of doubt, the present application includes the subject-matter described in the following numbered clauses:
The foregoing description is not intended to be exhaustive or to limit embodiments of the present disclosure to the precise form described, and modifications and variations are possible in light of the above teachings or may be acquired from practice of various examples. The features discussed herein were chosen and described in order to explain the principles and the nature of various examples and their practical application to enable one skilled in the art to utilize the present disclosure with various modifications as are suited to the particular use contemplated. Any and all combinations, subcombinations, and permutations of features described herein are the within the scope of the disclosure.
Number | Name | Date | Kind |
---|---|---|---|
2097810 | Dawes | Nov 1937 | A |
2184082 | Roberts | Dec 1939 | A |
2184261 | Vamos | Dec 1939 | A |
2188168 | Winkel | Jan 1940 | A |
2240816 | Tweedie | May 1941 | A |
2274085 | Mitulski | Feb 1942 | A |
2298941 | Herrmann | Oct 1942 | A |
2330459 | Tweedie | Sep 1943 | A |
2356268 | Phillips | Aug 1944 | A |
2421604 | Eaton | Jun 1947 | A |
2679117 | Reed | May 1954 | A |
3803731 | Zumbro | Apr 1974 | A |
4366634 | Giese | Jan 1983 | A |
5784806 | Wendt | Jul 1998 | A |
6785983 | Challe | Sep 2004 | B2 |
10472741 | Zeyrek | Nov 2019 | B2 |
20090107012 | Cheney | Apr 2009 | A1 |
20090272009 | Weisner et al. | Nov 2009 | A1 |
20120204448 | Bracken | Aug 2012 | A1 |
20130104420 | Heathcote | May 2013 | A1 |
20140352170 | Heathcote | Dec 2014 | A1 |
20170044695 | Hays | Feb 2017 | A1 |
20180064210 | Turner | Mar 2018 | A1 |
20180368500 | Pollock | Dec 2018 | A1 |
Number | Date | Country |
---|---|---|
206986458 | Feb 2018 | CN |
0123857 | Nov 1984 | EP |
S5336341 | Apr 1978 | JP |
2009125527 | Jun 2009 | JP |
Entry |
---|
I-Chin D. Tsai et al., The influence of woven stretch fabric properties on garment design and pattern construction, 2002, Institute of Measurement and Control, vol. 24 issue 1, pp. 3-14. (Year: 2002). |
Feb. 19, 2021—(WO) ISR—PCT/US20/06208. |
Stitch Guide, Most Common Stitch Types in ASTM D-6193 and ISO 4915:1991 Standards, Second Edition, Jun. 3, 2008; Retrieved from the Internet: <http://www.texup.eu/StitchGuide.pdf> [retrieved on Aug. 21, 2019]. |
Industrial Sewing Machines; Retrieved from the Internet: <https://www.slideshare.net/AmitDas125/industrial-sewing-machines> [retrieved on Aug. 18, 2019]. |
Juki, MCS-1500 Instruction Manual, 3-Needle, 2/3/4-Thread Cover Stitch Sewing Machine; Retrieved from the Internet: <https://www.juki.co.jp/household_en/serger/pdf/MCS-1500_manual.pdf> [retrieved on Aug. 18, 2019]. |
Mazadul Hasan Sheshir: “Stitch Types”, Southeast University, Department of Textile Engineering; Retrieved from the Internet: ,https://www.slideshare.net/sheshir/stitch-n-sesm-types-with-description. [retrieved on Aug. 18, 2019]. |
Number | Date | Country | |
---|---|---|---|
20210145123 A1 | May 2021 | US |