TEXTILE SHEET PRODUCT

CROSS-REFERENCE TO RELATED APPLICATIONS

Swiss Patent Application Nos. CH 000932/2023, filed 31 Aug. 2023, the priority document, corresponding to this invention, to which a foreign priority benefit is claimed under Title 35, United States Code, Section 119, and its entire teachings are incorporated, by reference, into this specification.

FIELD OF THE DISCLOSURE

The present invention lies in the field of textile technology, in particular for garments, and relates to a textile sheet product, an upper for a shoe and a shoe with such an upper.

BACKGROUND OF THE DISCLOSURE

Textile products are traditionally and most commonly produced as regular structures, for example as a knit or woven, or in irregular structures, such as a non-woven. While such techniques are reliable and established, they suffer from various drawbacks. For example, methods to tune the properties of the textile throughout the textile are significantly limited. For example, during knitting, it is hardly possible to provide a textile whose yarn has predefined locations a higher thickness than in others. Furthermore, providing cut-outs in the textile can be difficult, depending on the production technique this may loosen-up the textile structure and ultimately destroy the textile.

A drawback of shoe uppers having been made from such traditional textiles is that the force transmission during running from the foot of the wearer to the sole is inefficient. Often, significant portions of these forces are lost or not transmitted to the sole. For example, the knots in knits are relatively flexible, in particular with respect to loop movements relative to each other. This flexibility often prevents an efficient force transmission during running. As non-wovens are irregular structures, they also often cannot efficiently transmit force from the foot of the wearer via the upper to the sole.

Another drawback of such traditional textiles in shoe uppers is that they require significant human workforce as well as complicated and large textile production machines. Furthermore, these uppers can hardly be adjusted to the specific and individual properties and requirements of a runner's foot, but are often produced as bulk commodity in a few different sizes.

Another drawback of such traditional textiles is that they require a relatively large amount of material and are therefore relatively heavy. In particular for sports shoes, such as running shoes, or garments and bags, this is highly disadvantageous, since it accelerates wearer's fatigue and weakens their performance.

Furthermore, more recent approaches even focus on 3D-printing of regular structured textiles. For example, it has been described to manufacture the weft and warp yarn structures of a woven layer by layer by 3D-printing. This concept is for example described in WO2020/216606 A1 by the applicant. 3D-printing shows a significantly improved flexibility. For example, it is possible to vary the structure of a filament throughout the textile. It is possible to increase the thickness of a filament or even its material composition at predefined positions of the textile. However, 3D-printing of these filaments is relatively time consuming, which significantly increases production costs and is therefore typically not suited for bulk commodity products.

SUMMARY OF THE DISCLOSURE

It is the general object of the present invention to advance the state of the art in the field of textile technology and preferably to overcome the disadvantages discussed above fully or partly. It is further the object of the invention to provide a textile sheet product which can be used as an upper in a shoe which allows to efficiently transmit forces during running from the wearer's foot to the sole and thereby support the running movement. Furthermore, it is the object of the present invention to provide a textile sheet product which can be manufactured in a time efficient manner.

The general object is achieved by the subject matter of the independent claims. Further advantageous embodiments follow from the dependent claims and the overall disclosure.

In a first aspect, the invention relates to a textile sheet product. The textile sheet product comprises, or may in some embodiments consist of, a thermoplastic filament which extends along a filament path.

The thermoplastic filament may in some embodiments form along the filament path a plurality of superimposed loops and a plurality of crossings. At the crossings, the thermoplastic filament crosses and also contacts itself and forms a material-bonded, in particular fused, connection with itself.

A textile sheet product as used herein refers to a fiber-based, in particular filament-based, material. The textile sheet product may have a larger length and width than thickness. While the thickness may be defined by the fiber, particularly filament, thickness, the length and width is typically significantly larger. For example, while the thickness may be in the range of 50 micrometers to 0.5 cm, the length and width can for example be in the range of 10 cm or more.

It is generally understood herein that the term “comprising” is interpreted as meaning that it includes those features following this term, but that it does not exclude the presence of other features, as long as they do not render the claim unworkable. On the other hand, if the wording “consist of” is used, then no further features are present in the corresponding apart from the ones following said wording.

A filament path as used herein, describes the path the thermoplastic filament follows through the textile sheet product. In some embodiments, the filament path may be delimited by two opposing hypothetical boundary lines between which the superimposed loops formed extend. In certain embodiments, these two hypothetical boundary lines contact the outer periphery of the loops formed by the continuous filament. The two opposing hypothetical boundary lines may in certain sections extend linearly and/or in parallel to each other. However, the two hypothetical boundary lines and thus the filament path, may also form curves. In some embodiments, the filament path may cross itself or may overlap with itself.

The thermoplastic filament may comprise multiple filament sections, such as for example an upper and lower section as described herein, or also an intermediate section being for example arranged between two adjacent loops, respectively between an upper section of a first crossing of a first loop and a lower section of a second crossing of a second loop. There may also be a loop forming section which may form together with an upper and lower section a loop. The term “section” with reference to the filament typically refers to sections or areas along the extension direction of the filament.

A fused connection of the thermoplastic filament is a connection being formed by directly fusing at least two sections, in particular only two sections, of the thermoplastic filament together. A fused connection is devoid of an additional, i.e. external adhesive. A fused connection may be formed by providing at least one, or even both, of the filament sections in molten form. During curing (i.e. cooling below the filament melting temperature), a direct material-bonded connection is formed, which is devoid of external, respectively additional, adhesives.

A crossing as used herein is a structure at which the thermoplastic filament crosses and contacts itself. That is, a first section of the thermoplastic filament (such as an upper filament section) may cross a second section of the thermoplastic filament (such as a lower filament section). A loop as used herein is a section formed by the thermoplastic filament which starts at a crossing (e.g. a crossing formed by the thermoplastic filament which is part of the loop), extends, in particular continuously extends, along the thermoplastic filament and arrives again at the same crossing. A loop can have any desired shape. For example, the loops can be round and particularly circular or oval, such as elliptic, or they can be polygonal. Preferably the loops are round. Partially superimposed loops are loops which are partially arranged on top of each other and thus partially overlap. However, the loops are not completely aligned with each other, but offset to each other. In other words, the loops partially overlap with each other. In other words, the loops may in some embodiments form a helix, e.g. an oblique or offset helix. A crossing may for example be formed from two filament sections forming together a loop, i.e. the crossing is formed by a single loop. As another example, a crossing may also be formed from two filament sections forming different loops, i.e. such a crossing is formed by two or more overlapping loops.

Typically, the loops are consecutively arranged along the filament path one after another.

The thermoplastic filament may in some embodiments be a continuous filament. In certain embodiments, the continuous filament may form at least 100, in particular at least 1000, in particular at least 5000 loops. In some embodiments, the entire textile sheet product is formed of a single thermoplastic filament. Thus, in such embodiments, all superimposed loops and all crossings are formed by the single thermoplastic filament.

In some embodiments, at least one, or the majority (i.e. at least 50%), or at least 75%, or even all of the crossings consist of two filament sections which cross each other once. In some embodiments, a portion of the crossing formed by the thermoplastic filament comprises, or consists of, more than two filament section crossing each other, i.e. at the same position.

In some embodiments, the textile sheet product is a laid textile sheet product. In a laid textile sheet product, the loops are not inter-looped, respectively entangled or chain linked with each other. In contrast, the loops are arranged partially on top of each other, respectively stacked on each other, in particular along the filament path.

In some embodiments the plurality of superimposed loops are stacked on top of each other along the filament path. In some embodiments, the plurality of superimposed loops form a stacked structure. It is understood that the term “stacked on top of each other along the filament path” means that each subsequent (i.e. downstream) loop is arranged or shifted further downstream than the previous upstream loop. During production, this means that each downstream loop is formed after its upstream loops.

In some embodiments, the textile sheet product comprises a filament crossing density of at least 100 crossings per cm², in particular 200 crossings per cm², in particular at least 300 crossing per cm², more particular at least 400 crossings per cm², more particular at least 500 crossings per cm², more particular at least 600 crossings per cm², even more particular at least 700 crossings per cm².

In some embodiments, the textile sheet product comprises a filament crossing density of 200 to 10000 crossings per cm², in particular of 200 to 5000 crossings per cm², in particular of 300 to 5000 crossings per cm², in particular of 300 to 3000 crossings per cm², in particular of 400 to 3000 crossings per cm².

In some embodiments, the textile sheet product comprises a filament crossing density of 200 to 10000 crossings per cm², in particular 400 to 10000 crossings per cm², in particular of 400 to 5000 crossings per cm², in particular of 400 to 5000 crossings per cm², in particular of 400 to 3000 crossings per cm², of 400 to 3000 crossings per cm².

The number of crossings may be obtained from a corresponding microscopic image of the textile sheet product. For this a 1 cm×1 cm square is arranged on the microscopic image, in particular such that one of the four sides of the square extends through the center of a loop, e.g. such that the loop is divided in half by this side of the square. Such a crossing density provides an increased stability, in particular tearing strength, since any occurring forces are well distributed over a vast amount of crossings. Furthermore, due to the material-bonded connection, forces can be efficiently transmitted through the textile sheet product. This is particularly advantageous for shoe uppers comprising or consisting of such a thermoplastic textile material, because forces occurring during running and being exerted on the upper can be transmitted to the sole and thereby support the push-off process of the runner, which improves the runner's performance.

In some embodiments, the textile sheet product comprises a loop density as defined herein of 0.5 to 15 loops per cm², in particular 0.7 to 10 loops per cm², more particular 0.7 to 5 loops per cm². As used herein, the loop density is the number of loops being formed by the thermoplastic filament per cm². For this measurement, a surface of 4 cm²(2 cm×2 cm square) is arranged such that the center of a loop is aligned with the center of the 2 cm×2 cm square. For determining the loop density, only the number of loops which are completely (and thus not only partially) arranged inside the 2 cm×2 cm square is determined and divided by 4.

In some embodiments, the thermoplastic filament forms a plurality of fused bulge portions, formed from multiple fused together filament sections of the thermoplastic filament. In particular embodiments, the fused bulge portions are formed from at least two, in particular at least three, in particular at least four, in particular at least five, in particular at least six, filament sections being fused together. It is understood that the fused bulge portions are different from the formed crossings. In particular, fused bulge portions may have a larger cross-sectional area than a crossing, and/or length, i.e. extension in one direction in particular along the direction the filament extends. While a length of a crossing may for example be in the range of 100% to 300%, in particular 100% to 200% of the maximum filament thickness of the thermoplastic filament, respectively of the filament sections of the thermoplastic filament, a length, respectively extension in one direction of a fused bulge portion may be larger than 300%, in particular larger than 500% or even larger than 1000% of the maximum filament thickness of the thermoplastic filament, respectively of the filament sections of the thermoplastic filament. In general, fused bulge portions may be considered as a thickening in the textile sheet product as compared to the individual filament sections and optionally to the crossings.

In some embodiments, one or more fused bulge portions may extend along the filament path, e.g. in the filament path direction. In particular embodiments, one or more fused bulge portions may extend along, especially in parallel to, the plurality of loops. In some embodiments, two or more fused bulge portions of the textile sheet product are spaced apart from each other and extend essentially at least over a portion of the textile sheet product in parallel to each other.

In certain embodiments, multiple sections of the formed loops may be fused together in such fused bulge portions. Fused bulge portions generally have the advantage that the tearing strength and the general stability of the textile sheet product is significantly increased. The fused bulge portions may for example be formed by multiple filament sections which merge together at the bulge portion and/or which diverge from each other from the fused bulge portion. The fused bulge portions may in some embodiments have an extension in one direction of 1 mm or more, in particular of 10 mm or more, in particular of 20 mm or more. It is understood that the bulge portion has a larger thickness than the maximum filament thickness of the individual thermoplastic filament sections. The fused bulge portions may in some embodiments also comprise one or more crossings formed by the thermoplastic filament. In such embodiments, the crossings are fused into the fused bulge portion.

In some embodiments, the textile sheet product has a longitudinal elongation (along the direction of the filament path) at break according to test method 1 as described herein, of 15 to 100 N, in particular of 20 to 70 N, more particular of 20 to 60 N.

In some embodiments the textile sheet product has a transversal elongation (along the direction perpendicular to the direction of the filament path) at break according to test method 1 as described herein, of 10 to 70 N, in particular of 150 to 50 N, more particular of 15 to 40 N.

In some embodiments the transversal elongation at break of the textile sheet product (as determined according to test method 1 as described herein) is smaller than the longitudinal elongation at break (as determined according to test method 1 as described herein). In particular, the transversal elongation at break may be at least 1 N smaller, in particular at least 2.5 N smaller, more particular at least 5 N smaller, than the longitudinal direction at break.

Test method 1 is a tensile test method. The textile sheet product is positioned and fixed to and between two holders such that it is evenly held between the holders but not stretched (this corresponds to initial force F₀an initial distance d₀, d₀may be set to 100 mm, that is the two holders are 100 mm spaced apart from each other and a single layer of the textile sheet product is positioned and fixed in between). Then the holders are moved apart from each other to stretch the textile sheet product with a speed of 1 m/min. The force F is determined in dependence of the elongation distance d (i.e. the distance the holders are moved apart from each other) is determined. The force at which the textile sheet product tears apart represents then the elongation at break.

In some embodiments, the textile sheet product is configured such that it elastically returns to its original shape and/or configuration upon stretching the textile sheet product in at least one direction.

In some embodiments, the thermoplastic filament and in particular the loops, define polygonal, e.g. essentially rhombic, or round (in particular oval, elliptic or circular) openings. These polygonal or round openings may be through going opening, which penetrate through the textile sheet material.

In some embodiments, the thermoplastic filament and in particular the loops, define triangular openings. These triangular openings may be through going opening, which penetrate through the textile sheet material.

In some embodiments, the partially superimposed loops are along the filament path arranged one after another and at least some, or the majority (more than 50%), or essentially all, of the superimposed loops, except the last loop (along the filament path) are arranged (e.g. partially arranged) underneath their next adjacently arranged loop. In other words, in such embodiments, the superimposed loops form together a roof tile structure in which the superimposed loops partially overlap and in which starting from the first loop, every loop except the last one is arranged partially underneath its next adjacent loop. Such a structure with fused crossings not only provides for a significantly resistant and stable textile sheet product, but can also be manufactured relatively easily as will be described further below.

In this context, the directional indications “downstream” refer to a direction along the filament path. In contrast “upstream” refers to the opposite direction, i.e. against the filament path. That is, a specific loop B may be arranged downstream of a specific loop A. In the embodiments described in the preceding paragraph this may mean that if loops A and B are arranged directly one after another, the loop being arranged downstream, i.e. loop B, is arranged above loop A, i.e. on top of it. Vice versa. The upstream loop, i.e. loop A is arranged underneath the downstream loop B. In general, in some embodiments the loops, in particular each loop, may be arranged underneath its adjacent downstream loop.

The filament path may have a filament path direction. This filament path direction may extend from the first loop formed by the thermoplastic filament through the center of each subsequent loop up along the textile sheet product up to the last loop formed by the thermoplastic filament. The filament path direction does not have to be linear, but may also form curves through the textile sheet product. In the filament direction, the loops, in particular each loop, may preferably be arranged underneath its next adjacently arranged loop.

In some embodiments, each partially superimposed loop (except the last loop) is along the filament path arranged underneath their at least 2, at least 5, at least 10, or at least 15, next adjacently arranged loops. Thus, in such embodiments, the loops form a relatively narrow loop structure which results in an increased number of crossings and thus to a significantly more resistant textile sheet product. In some embodiments the loops, in particular each loop, may be arranged underneath its at least 2, at least 5, at least 10, or at least 15, adjacent downstream loops.

In some embodiments, each loop formed by the thermoplastic filament defines a maximum clear distance of 5 mm to 50 mm, in particular 5 mm to 30 mm. The maximum clear distance is the maximum length of a straight line extending through the center of the loop through the open area defined by the inner periphery of the thermoplastic filament forming the corresponding loop. For example, if the loop is circular, the maximum clearing distance is equal to the inner diameter of the loop.

In some embodiments, the maximum clear distance of the loops formed by the thermoplastic filament may vary throughout the textile sheet product, in particular by at least 10%, particularly at least 20%, more particularly at least 30%, or by between 10% to 50%, particularly between 20% to 50%. Such a varying maximum clear distance influences the properties of the textile sheet product. For example, a larger maximum clear distance may lead to a larger open area and thus lead to a more breathable and lighter region. In contrast, a smaller maximum clear distance leads to a decreased open area and a higher loop density which improves the stability and the force transmission in this region. For example, the textile sheet product may comprise a first area with a plurality of loops in which each loop has a smaller maximum clear distance than each loop in a second area with a plurality of loops, or in which the mean maximum clear distance of the loops is smaller than the mean maximum clear distance of the loops in the second area. It is understood that the textile sheet product may also comprise multiple of such first and second areas.

In some embodiments, the thermoplastic filament and/or thermoplastic filament sections (e.g. individual filament sections which form the loops and/or the crossings), has a maximum filament thickness of 10 μm to 1000 μm, in particular 50 μm to 500 μm, more particular of 50 μm to 300 μm, even more particular of 75 μm to 250 μm. The maximum filament thickness is the maximum cross-sectional extension of the thermoplastic filament, respectively the filament sections. However, it should be noted that the maximum filament thickness is not measured at a fused bulge portion or at a crossing, but rather at a section of the thermoplastic filament where it forms a loop and where is not fused to other sections of the thermoplastic filament. If the thermoplastic filament has a circular cross-section, the maximum filament thickness is equal to the diameter of the thermoplastic filament. This term does however not mean that it refers to the largest filament thickness along the entire filament length, but the term “maximum” means that if the cross-section of the thermoplastic filament is for example rectangular, the maximum filament thickness is given by the diagonal between two corners and not for example by the lengths of the sides of the rectangle, since the diagonal is the largest filament thickness at this position.

In some embodiments, the superimposed loops of the textile sheet product form a regular laying pattern. A regular laying pattern is a laid pattern, which comprises at least one regularly repeating element, such as regularly repeating loops.

In some embodiments, each crossing is at least formed, or only formed, from a lower filament section of the thermoplastic filament and an upper filament section of the thermoplastic filament. The upper filament section is arranged above, i.e. on top of, the lower filament section. It is understood that the lower and upper filament sections are different sections of the thermoplastic filament, in particular of the same thermoplastic filament, which are along the thermoplastic filament spaced apart from each other. For example, a loop formed by the thermoplastic filament may commence at a lower filament section at a crossing extend along the loop and end at the upper filament section at this crossing being arranged above the lower filament section. In particular, at least one, or the majority (i.e. more than 50%) or even all of the crossings is/are formed only from a lower filament section of the thermoplastic filament and an upper filament section of the thermoplastic filament.

In some embodiments, the upper filament section at at least one, or at the majority (i.e. more than 50%), or at all crossings, is sank partially into the lower filament section. In such embodiments, the lower filament section may form a concavity, such as a bowl shaped, U shaped or V shaped concavity which accommodates a part of the upper filament section at the corresponding crossing. Such crossings may for example be formed by providing the upper filament section onto the lower filament section while the lower filament section is in a softened, e.g. molten, state. Such crossing provide for an improved stability, in particular tearing resistance, since it forms a stronger connection between the filament sections.

In some embodiments, the upper filament section is sank into the lower filament section by between 40% to 90%, in particular by between 50% to 90%, more particular by between 60% to 80% of its maximum filament thickness.

In some embodiments the upper filament section is at at least one, or at the majority (i.e. more than 50%), or at all crossings, sank such into the lower filament section that the crossing has a height being between 10% to 50%, in particular 15% to 30% larger than the maximum filament thickness. In some embodiments, the height of at least one, or at the majority (i.e. more than 50%), or at all crossings is between 10% to 50%, in particular 15% to 30% larger than the maximum filament thickness. It is understood that the term “height” as used herein is typically perpendicular to the two filament sections crossing each other at the crossing, respectively extends along the thickness of the textile sheet product.

In some embodiments, the height at at least one, or at the majority (i.e. more than 50%), or at all crossings is between 10 to 50 μm, in particular 10 to 30 μm larger, than the maximum filament thickness.

In some embodiments, at least one, or the majority (i.e. more than 50%), or all crossings, have a crossing length, i.e. the total extension of crossing along each filament section of the crossing (i.e. the upper or lower filament section) of between 50 to 500 μm, in particular 50 to 250 μm, more particular 100 to 200 μm.

In some embodiments, the at least one, or the majority (i.e. more than 50%), or even all of the crossings may comprise or be a protuberance. Such a protuberance may generally be formed by the thermoplastic filament. Such a protuberance comprises a height being larger than the maximum filament thickness of the thermoplastic filament. Typically, the height of the protuberance may be between >100% and 200%, in particular >100% to 180%, more particular between 110% and 160%, of the maximum filament thickness of the thermoplastic filament.

In some embodiments, the textile sheet product is formed from a single thermoplastic filament.

In some embodiments, the thermoplastic filament has a filament length of at least at least 0.1 m, in particular at least 1 m, more particular at least 100 m, more particular at least 1000 m.

In some embodiments, the thermoplastic filament has a filament length of at most 10000 m, in particular at most 5000 m, in particular at most 2500 m.

In some embodiments, the thermoplastic filament as a filament loop length per loop (i.e. the extension of the thermoplastic filament from a crossing along the loop and back to the crossing) of 0.1 cm to 50 cm, in particular 0.25 cm to 10 cm, more particular 0.5 cm to 5 cm.

In some embodiments, the textile sheet product comprises a first area and a second area being different from the first area. It is understood that the textile sheet product may also comprise a plurality of such first areas and a plurality of such second areas. In this case each of the plurality of the first areas may have the same properties but are arranged at different locations and/or are spaced apart from another. Vice versa, the plurality of the second areas may have the same properties but are arranged at different locations and/or are spaced apart from another. Particularly, the first area differs in at least one property from the second area. For example, the different property, such as a physical property, particularly a mechanical property, may be a different mass per area, different maximum clear distance, different loop density, different filament crossing density, mesh size, etc.

In some embodiments, the filament crossing density is higher in the first area than in the second area. In certain embodiments, a ratio of filament crossing density in the second area to the filament crossing density in the first area is between 0.05 to 0.5 in particular 0.1 to 0.5. Such embodiments allow to provide areas with an increased stability and decreased flexibility (higher filament crossing density), which may be beneficial in areas which are in use exposed to mechanical forces, such as abrasion, and areas increased flexibility for areas, where a certain flexibility is desirable.

In some embodiments, the loop density in the first area is higher than in the second area. In certain embodiments, the ratio of the loop density in the second area to the loop density in the first area is between 0.05 to 0.6, in particular 0.1 to 0.5. An increased loop density provides for a higher stability, which is beneficial in areas being exposed to high mechanical forces, whereas a decreased loop density leads to a better breathability and/or higher mesh size. In a shoe upper, this may be beneficial for the instep region, i.e. the region extending from the medial side to the lateral side of the instep of the wearer's foot, where the tongue and the lacing is arranged in a common shoe. Such embodiments are advantageous, because a decreased loop density reduces the overall weight of the upper and concomitantly allows for a higher breathability which improves the wearing comfort.

In some embodiments the thermoplastic filament comprises along the loops, in particular along each loop, except the first and last loop, a crossing number as defined herein of at least 10, in particular at least 20, in particular at least 30, in particular at least 50, in particular at least 100, in particular at least 200.

In some embodiments, the thermoplastic filament comprises along the loops, in particular along each loop, except the first and last loop, a crossing number as defined herein of 10 to 5000, in particular 10 to 1000, in particular 20 to 500, more particular 30 to 500, more particular 50 to 500, more particular 50 to 300.

The crossing number along the loops, in particular each loop, as defined herein is the number of crossings formed at different positions when staring at any crossing of the corresponding loop and counting the number of crossings formed by this loop until one comes back to the crossing of this loop at which one has started.

In some embodiments, the thermoplastic filament encloses a plurality of air bubbles. Such bubbles improve the stretchability, respectively elasticity, of the textile sheet product.

In certain embodiments, the different property of the first area and the second area may be a different crossing number along the loops, in particular each loop, in these areas. For example, the crossing number in the first area may be higher than in the second area. It may for example be possible that the ratio of the crossing number along the loops, in particular each loop, in the second area to the crossing number along the loops, in particular each loop, in the first area may be between 0.05 to 0.7, in particular 0.1 to 0.7.

In some embodiments, the thermoplastic filament consists of polymer chains. Preferably, the polymer chains of the thermoplastic filament are aligned with each other, i.e. on an intermolecular level aligned with each other. This means that the polymer chains extend along the thermoplastic filament essentially in parallel to each other. This may be achieved by stretching the textile sheet product directly after its production, e.g. during curing. Such textile sheet products have the advantage that they show an increased force transmission throughout the textile sheet product.

In some embodiments, the filament path partially overlaps with itself within the textile sheet product. For example, it may be the case that the filament path partially overlaps with itself within certain portions of the textile sheet product. It may for example be the case that a first section of the filament path which comprises or consists of a plurality of superimposed loops is partially overlapped by a second section of the filament path. The second section of the filament path may for example be arranged downstream along the filament path of the first section of the filament path. Such a first and second section which partially overlap each other may in some embodiments be consecutively, i.e. directly adjacently, behind each other, or they may be separated from each other by an intermediate section of the filament path. In such embodiments, a loop of the first section of the filament path may on the one hand be arranged underneath a next adjacently arranged (i.e. downstream) loop or multiple loops of the first section, and on the other hand also underneath loops being arranged along the filament path in the second section of the filament path, i.e. downstream of the first section of the filament path. As an example, the first section of the filament path may be linear in a first direction x and the second section of the filament path may also be linear, but extend in the opposite direction −x. Since the first and second section only partially overlap, they are in another direction, e.g. in the y direction being perpendicular to direction x and −x, offset to each other. It may in another embodiment be the case that the filament path has the shape of a helix or a spiral, wherein the filament path overlaps itself within the textile sheet product. That is, a first section of the filament path may be represented by the outermost coil of the helix or spiral. A second section of the filament path may be arranged downstream, e.g. directly adjacent the first section forming a second coil and partially overlapping the first section. This second coil is arranged closer to the helix' or spiral's center. Then, a third section of the filament path may be arranged downstream of the second section in the shape of a third coil and partially overlapping the second section of the filament path. This may be repeated multiple times, e.g. with a 4^th, 5^th, 6^th, 7^th, 8^th, 9^thor 10^thsection of the filament path up to the helix' or spiral's center.

In general, a textile sheet product as described with respect to the first aspect of the invention may be provided by a production method. The production method may comprise providing a molten thermoplastic polymer material as a molten thermoplastic filament to a surface. The surface may in certain embodiments be a shoe last. The production method may further comprise depositing the molten thermoplastic filament on the surface such that it forms a plurality of superimposed loops and that it forms a plurality of crossings with itself. Since the thermoplastic filament is deposited in molten form, it will form a material-bonded connection with itself at the crossings. Depositing may for example be performed by a nozzle which deposits the molten filament in such a manner, for example be a suitable movement of the nozzle and/or also the molten filament, that it forms superimposed loops on the surface. Thereafter, the deposited molten filament is cured, which may for example comprise solidification by cooling the thermoplastic filament below its melting temperature.

In some embodiments, the molten thermoplastic filament may be provided to the surface with a velocity of at least 0.1 m/s, in particular at least 0.5 m/s, more particular at least 0.7 m/s. In some embodiments, the molten thermoplastic filament may be provided to the surface with a velocity of between 0.1 m/s to 10 m/s, in particular between 0.1 m/s to 5 m/s, more particular between 0.1 m/s to 1 m/s. In some embodiments, the molten thermoplastic filament may be provided to the surface with a velocity of between 0.5 m/s to 10 m/s, in particular between 0.5 m/s to 5 m/s, more particular between 0.5 m/s to 1 m/s. In some embodiments the molten thermoplastic filament may be provided to the surface with a velocity of between 0.7 m/s to 10 m/s, in particular between 0.7 m/s to 5 m/s, more particular between 0.7 m/s to 1 m/s.

In some embodiments, the textile sheet product comprises at least one yarn. The at least one yarn may be fused to the thermoplastic filament. Such a yarn may additionally reinforce the textile sheet product.

A second aspect of the invention relates to an upper for a shoe (i.e. a shoe upper), which comprises, or consists of, the textile sheet product described in any of the embodiments herein, in particular with respect to the first aspect of the invention.

The upper may for example in some embodiments comprise a medial side and a lateral side. The upper may further comprise a heel area with a heel edge, a forefoot area with a tip and a midfoot area being arranged between the heel area and the forefoot area. The heel edge represents along the longitudinal direction the rear delimitation of the upper and extends on the worn state being used in a shoe along the wearer's Achilles' tendon. The tip is oppositely arranged to the heel edge and represents in the worn state being used in a shoe, the foremost delimitation of the upper. The upper may further comprise an instep area which extends from the medial side of the upper to the lateral side of the upper and in the worn state and being used in a shoe over the wearer's instep. In conventional uppers, the instep area is formed by the tongue and the lacing. Furthermore, the upper may comprise a peripheral bottom section. The peripheral bottom section represents on the medial and lateral side the peripheral delimitation of the upper. When used in a shoe, the peripheral bottom section is typically connected to the sole and forms the interface to the sole, respectively the connection area.

Directional indications as used in the present disclosure are to be understood as follows: The longitudinal direction LO of the upper, respectively the shoe, is described by an axis from the heel area, respectively, from the heel edge, to the forefoot area, respectively to the tip, and thus extends along the longitudinal axis of the upper, respectively the shoe. The transverse direction TR of the upper, respectively the shoe, extends transversely to the longitudinal axis substantially parallel to the ground in the worn state. Thus, the transverse direction runs along a transverse axis of the upper, respectively the shoe. In the context of the present invention, the vertical direction V runs along a vertical axis of the upper, respectively the shoe. The longitudinal direction, the vertical direction and the transverse direction may all be perpendicular to each other. The lateral side of the upper, respectively the shoe, is the outer perimeter of the upper, respectively the shoe, between the heel edge and the tip, which in the worn state rests against the outer instep of the wearer's foot. The medial side of the upper, respectively the shoe, refers to the inner perimeter of the upper, respectively the shoe, between the heel edge and the tip, which is located opposite the lateral side. Thus, in a pair of worn shoes, the medial sides of the two running shoes face each other and the lateral sides face away from each other. Both the medial side and the lateral side each extend from the heel edge to the tip and meet each other at the tip and the heel edge. Furthermore, the upper, respectively the shoe, may typically along the longitudinal direction be divided into a forefoot area, a heel area and a midfoot area being arranged between the forefoot area and the heel area. For example, the forefoot area extends from the tip against, i.e. opposite, the longitudinal direction to 30-45% of the total length of the upper, respectively the shoe, in the longitudinal direction. The heel area extends, for example, from the heel edge in the longitudinal direction to 20-30% of the total length of the upper, respectively the shoe, in the longitudinal direction. The midfoot area extends directly between the heel area and the forefoot area, such that the length in the longitudinal direction of the midfoot area makes up the remaining portion of the total length, particularly from 15-50% of the total length.

In some embodiments, the upper may consist of the textile sheet product.

In some embodiments, the textile sheet product of the upper may consist of a single thermoplastic filament, in particular a single uninterrupted thermoplastic filament.

In some embodiments, the upper is devoid of a lacing and/or any eyelets.

In some embodiments, the upper comprises as the first area of the textile sheet product one or more reinforcement band structures. These reinforcement band structures may have a higher filament crossing density, and/or a higher loop density, and/or a higher crossing number along each loop than the second area of the upper, in particular the textile sheet product. It is understood that such a first area and second area may be a first area and a second area as described with respect to the textile sheet product in the first aspect of the invention. Such reinforcement band structures are advantageous, as they provide for areas with increased stability and better force transmission. For example, areas which are exposed to significant forces can be reinforced by such structures without significantly increasing the overall weight of the upper.

In some embodiments, one or more of the reinforcement band structures extend from the medial side of the upper over the instep area of the upper to the lateral side of the upper. This is advantageous, because by arranging reinforcement band structures in this manner, these areas are reinforced, which secures the upper tightly to the wearer's foot. This may allow to dispense with any lacing system, which would otherwise be detrimental for the overall weight of the upper.

In some embodiments, one or more of the reinforcement band structures are arranged in the midfoot area and/or in the forefoot area and/or in the heel area of the upper. In particular embodiments, the upper may comprise a plurality of reinforcement band structures, particularly separate reinforcement structures, wherein at least one reinforcement band structure is arranged in the heel area, at least one in the midfoot area and at least one in the forefoot area. These may particularly all be separate reinforcement band structures.

In some embodiments, one of the one or more reinforcement band structures extends both on the medial side and on the lateral side towards the tip of the upper. This means, such a reinforcement band structure forms in a 2D representation a U-shape or V-shape pointing towards the tip, respectively around the foot access opening of the upper.

In some embodiments, the one of the one or more reinforcement band structures extends on the medial side and on the lateral side towards the heel edge of the upper. This is the inverse arrangement of the one discussed above. This means, such a reinforcement band structure forms in a 2D representation a U-shape or V-shape pointing towards the heel edge, respectively towards the foot access opening of the upper.

In some embodiments, the one or more of the reinforcement band structures are arranged at the peripheral bottom section of the upper, in particular in the forefoot area of the upper and/or on the lateral side of the upper. Such embodiments are advantageous, because the peripheral bottom section of the upper is in a shoe and during running exposed to significant forces. This holds particularly true for the lateral side, especially in the midfoot and forefoot area, when the runner changes directions, e.g. during running a curved track.

In some embodiments, the upper defines a foot access opening. In certain embodiments, one or more of the reinforcement band structures is circumferentially arranged around the foot access opening. This has the advantage that the area around the foot access opening is reinforced. This area is particularly during putting a shoe with such an upper on or off exposed to higher tearing forces and thus such embodiments have an increased product lifetime.

In some embodiments, one of the reinforcement band structures extends on the lateral side and at least in the midfoot area along the longitudinal direction of the upper, in particular linearly, for example over at least 5 mm, or at least 50 mm. As the lateral side is during sports exposed to significant forces, such a reinforcement band structure is beneficial.

In some embodiments, one of the reinforcement band structures extends on the medial side and at least in the midfoot area along a longitudinal direction of the upper, in particular linearly, for example over at least 5 mm, or at least 50 mm. On the medial side, such a reinforcement band structure may increase the fit of the upper on the wearer's foot and thus increase the wearing comfort.

In some embodiments, one of the reinforcement band structures extends, in particular linearly, for example over at least 5 mm, or at least 50 mm, from the medial side of the upper around the heel edge to the lateral side of the upper. Preferably, such a reinforcement band structure is arranged such that in the worn state, it surrounds the wearer's Achilles tendon. Such embodiments improve the fit of the upper and a corresponding shoe, and increases the wearing comfort. In particular, it may avoid, even in the absence of a lacing system that the foot of the wearer is removed from a foot accommodation compartment defined by the upper, respectively moved out of the foot access opening.

In some embodiments, the upper comprises a second area of the textile sheet product at least in the instep area of the upper, in particular in the center of the upper. The center of the upper extends along the longitudinal direction of the upper. In a conventional running shoe, the tongue area extends through the center of the upper. Such a second area may be a second area as described herein above, for example with respect to the first aspect and/or the second aspect of the invention. The second area may for example have a lower filament crossing density, and/or a lower loop density, and/or a lower crossing number along each loop than another area, such as a first area, particularly as described herein.

In some embodiments, the upper delimits one or more through-going cut-outs. A cut-out is an opening defined by the upper which completely penetrates the upper. Such a cut-out has an open area of at least 20 mm², in particular at 100 mm², more particular at least 250 mm², more particular at least 500 mm². Cut-outs may in one plane preferably be completely circumferentially surrounded, respectively delimited by the upper. A cut-out does not necessarily have to be produced by cutting out a piece from a finished upper. The term cut-out also encompasses embodiments in which the cut-out was there from the beginning, i.e. planned during manufacture. Cut-outs may be arranged in areas in which basically no upper material must be present without significantly decreasing its stability. This is beneficial as it decreases the overall weight of the upper and increases the breathability. For example, such a cut-out may be arranged in the instep area of the upper.

In some embodiments, the upper, and in particular the thermoplastic filament of the textile sheet product, has a weight of 15 g to 50 g, in particular 15 g to 30 g.

In some embodiments, the upper is devoid of any stitching in particular devoid of any spun yarn.

A third aspect of the invention relates to a shoe which comprises an upper according to any of the embodiments as described herein, in particular with respect to the second aspect of the invention. It is understood that the shoe may comprise therefore also a textile sheet product according to any of the embodiments described herein, in particular with respect to the first aspect of the invention.

The shoe may also comprise a sole unit which is connected to the upper in a connection area. The upper defines a foot accommodation compartment and a foot access opening providing access to the foot accommodation compartment, in particular providing access for the wearer's foot.

In some embodiments, the filament path along which the partially superimposed loops are formed, extends helically and in particular helically around the foot accommodation compartment, from the connection area towards the foot access opening. For example, the filament path may partially overlap itself. Thus, in such embodiments, not only a certain number of directly adjacent loops along the filament path are partially superimposed with each other, but also loops which are arranged further along the filament path. This means, a given loop may be partially superimposed with a certain number of the along the filament path next adjacently arranged loops, then there follow along the filament path a certain number of loops with which the given loop is not superimposed, but from which it is spaced apart, and then there follows a certain number of loops along the filament path with which the given loop is partially superimposed. The latter may be spaced apart from the given loop by essentially one helical coil. It is understood that the filament path does not need to form a regular helix having a constant radius, pitch and/or slope, although this may in some embodiments be the case.

A fourth aspect of the invention relates to a garment, such as a t-shirt, a sweatshirt, a vest, a jacket, a pullover, shorts, a pant, a glove, a hat, a sock or the like, wherein the garment comprises or consists of the textile sheet product according to any of the embodiments described herein, in particular with respect to the first aspect of the invention.

A fifth aspect of the invention relates to a bag, such as a carrier bag, a purse, a wallet, a backpack, a duffel bag or the like, wherein the bag comprises or consists of the textile sheet product according to any of the embodiments described herein, in particular with respect to the first aspect of the invention. Such a bag typically defines a goods accommodation compartment which is at least partially or completely delimited by the textile sheet product.

BRIEF DESCRIPTION OF SEVERAL VIEWS OF THE DRAWINGS

The herein described invention will be more fully understood from the detailed description given herein below and the accompanying drawings which should not be considered limiting to the invention described in the appended claims.

FIG. 1 shows a schematic representation of a textile sheet product according to an embodiment of the invention;

FIG. 2 shows a schematic representation of a textile sheet product according to another embodiment of the invention;

FIG. 3 shows a schematic representation of a shoe with an upper comprising a textile sheet product according to an embodiment of the invention;

FIG. 4 shows a schematic representation of a shoe with an upper comprising a textile sheet product according to another embodiment of the invention;

FIG. 5 shows a schematic representation of a shoe with an upper comprising a textile sheet product according to another embodiment of the invention;

FIG. 6 shows a microscopic image of a portion of a textile sheet product according to an embodiment of the invention;

FIG. 7 shows a microscopic image of a portion of a textile sheet product according to an embodiment of the invention;

FIG. 8 shows a microscopic image of a portion of a textile sheet product according to an embodiment of the invention;

FIG. 9 shows a microscopic image of a portion of a textile sheet product according to an embodiment of the invention; and

FIG. 10 shows a microscopic image of a portion of a textile sheet product according to an embodiment of the invention.

DESCRIPTION OF THE EMBODIMENTS

FIG. 1 shows a schematic representation of a textile sheet product 1 according to an embodiment of the invention. Textile sheet product 1 comprises thermoplastic filament 2 which extends along filament path 3. Filament path 3 is arranged between the two parallel dashed lines, which are aligned with the outer periphery of the loops firmed by thermoplastic filament 2. The filament path direction is indicated by the dashed arrow extending from upstream U to downstream D. It can be seen that thermoplastic filament 2 forms the entire textile sheet product 1. Thermoplastic filament 2 forms a plurality of superimposed loops L1, L2 (only two loops are referenced for clarity purposes). Each loop has a maximum clear distance d (indicated for loop L1). Furthermore, thermoplastic filament forms a plurality crossings c1, c2, c3, c4, c5, c5, c7, c8, c9, c10, c11 and c12 at which it crosses itself and at which it forms a direct, i.e. inherent, material-bonded connection with itself. Each of the crossings is formed from a lower filament section of the thermoplastic filament 2 and an upper filament section which is arranged on the lower filament section.

In FIG. 1 the thermoplastic filament is drawn with discontinuations at the crossing. This should not be interpreted as a break in the thermoplastic filament but merely serves to indicate which filament section is at each crossing on top and which below the other one. Thermoplastic filament 2 is in fact continuous throughout each of the loops shown. Loop L1 commences at its first crossing c1 along the filament path direction and ends again at crossing c1. Accordingly, loop L2 starts and ends at crossing c5. By virtue of the arrangement of thermoplastic filament 2 and in particular by the loops L1, L2, etc., a regular laid pattern is formed. The loops are not entangled with each other but rest on top of each other, that is, they form a laying or stack, respectively a laid or stacked textile sheet product.

As can be seen, the loops formed by thermoplastic filament 2 are along filament path 3 in the filament path direction arranged one after another (that is, loop L1 is followed by loop L2, which is followed by subsequent loops). The superimposed loops are along the filament path arranged underneath their along the filament path 3 and in the filament path direction next adjacently arranged loop. For example, in FIG. 1 it can be seen that loop L1 is arranged underneath loop L2. In general, a loop (except the first loop L1) is arranged at least underneath its next downstream arranged loop (for example loop L1 is arranged underneath loop L2). However, as it is shown in FIG. 1, loop L1 is not only arranged underneath downstream loop L2, but also underneath the next downstream loop (see crossings c3 and c5). Thermoplastic filament 2 has a maximum filament thickness t as shown in FIG. 1.

Detailed view Z shows a schematic cross-sectional view through a crossing formed by thermoplastic filament 2. It can be seen that the crossing is formed from a corresponding lower filament section 2a and an upper filament section 2b, while the upper filament section 2b is partially, but not completely sank into the lower filament section 2a.

Loop L2 shown in FIG. 1 has a crossing number along the loop of 8 (crossing c7, c8, c9, c10, c11, c12, c6, c2).

FIG. 2 shows a schematic view of a textile sheet product 1 according to another embodiment of the invention. In contrast to FIG. 1 where the filament path extends linearly, the filament path along which thermoplastic filament 2 forms loops L3, L4, L5 and L7 does not extend only linearly, but comprises two curves, respectively two changes of direction as shown by the dashed arrow. In FIG. 2, the loops L3, L4, L5 and L7 are highlighted for illustrative purposes. Also in this embodiment, thermoplastic filament 2 forms a plurality of crossings with itself at which it forms a material-bonded connection with itself. As can be seen, the filament path overlaps itself in this embodiment. This has the effect that for example loop L3 is not only arranged underneath its directly adjacent loops L4 and L5, but also underneath much further downstream arranged loop L6. The upper part of the filament path, which comprises loops L3, L4 and L5 and which extends linearly up to the loop where the dashed arrow and thus the filament path undergoes a first directional change, can be considered a first section of the filament path. The lower part of the filament path, which comprises loop L6 and which extends linearly from the loop where the dashed arrow and thus the filament path undergoes a second directional change up to the last loop, can be considered a second section of the filament path. It can be seen that the second section of the filament path overlaps the first section of the filament path. This increases the crossing number of loop L3 as compared to loop L2 shown in FIG. 1. The crossing number along loop L3 in FIG. 2 is 15. Since each crossing forms a direct material-bonded connection, the textile sheet product 1 shown in FIG. 2 has an enhanced tear resistance and shows a better force transmission through textile sheet product 1.

FIG. 3 shows a shoe 100 with upper 4 and sole unit 6 being connected together in connection area 9. The upper defines a foot accommodation compartment and further foot access opening 5 which allows to introduce a foot of a wearer into foot accommodation compartment. As can be seen, the upper is devoid of laces, which is enabled by the tight and reliable fit of upper 4. Upper 4 comprises, respectively in this embodiment consists of, textile sheet product 1. The corresponding thermoplastic filament of the textile sheet product is for clarity purposes only drawn in the bottom right part in the heel area of upper 4, however it is understood that the thermoplastic filament and the formed loops and crossings extend over the entire upper. Filament path 3 along which the loops are formed extends helically from connection area 9 towards foot access opening 5. Typically, the filament path 3 overlaps with itself in such embodiments. It can be seen that the helix along which filament path 3 extends is not a regular helix, however as it can be seen, the filament path extends along a first coil along, or even within connection area 9. Then, the next adjacent coil of the formed helix is arranged closer to foot access opening 5 and so on, until filament path 3 reaches foot access opening 5.

FIG. 4 shows another embodiment of a shoe 100 having upper 4 and sole unit 6. Again, upper 4 comprises, or consists of, textile sheet product 1, which comprises or consists of a thermoplastic filament which forms a plurality of loops along a filament path and which forms a plurality of crossings at which the thermoplastic filament crosses itself and forms a material-bonded, particularly fused, connection with itself. For clarity purposes, the thermoplastic filament and the formed loops and crossings are not shown. Upper 4 comprises a plurality of reinforcement band structures 7a, 7b and 7c. Each of these reinforcement band structures represent a first area of the upper. These first areas are each different in at least one property from second area 8a which is in this embodiment arranged between reinforcement band structures 7a and 7b. In this embodiment, reinforcement band structures 7a, 7b and 7c may for example have a higher loop density and/or a higher filament crossing density and/or a higher crossing number along each loop than second area 8a.

Both reinforcement band structures 7a and 7b extend from the lateral side facing the viewer in FIG. 4, over the instep area IA to the medial side facing to the back. Reinforcement band structure 7a extends on the lateral side and on the medial side towards tip 10 and thus forms in a 2D representation a U-shape pointing towards tip 10. In contrast, reinforcement band structure 7b is oppositely arranged. That is, on both the medial and lateral side, it extends towards heel edge 11, respectively towards foot access opening 5 and thus forms in a 2D representation a U-shape pointing away from tip 10 and towards heel edge 11, respectively towards foot access opening 5. In addition, reinforcement band structure 7c circumferentially surrounds foot access opening 5 and thereby provides for a higher stability in this area which is beneficial as this area is exposed to higher forces during pulling on or off shoe 100. It can further be seen that upper 4 comprises a heel area HA, a forefoot area FA and a there between arranged midfoot area MA.

FIG. 5 shows another embodiment of a shoe 100 which also comprises upper 4 and sole unit 6. Again, upper 4 comprises, or consists of, textile sheet product 1, which comprises or consists of a thermoplastic filament which forms a plurality of loops along a filament path and which forms a plurality of crossings at which the thermoplastic filament crosses itself and forms a material-bonded, particularly fused, connection with itself. For clarity purposes, the thermoplastic filament and the formed loops and crossings are not shown. Upper 4 comprises first areas 7d, 7e and 7f as well as second area 8b. Also in this embodiment, the first areas are reinforcement band structures. These first areas are each different in at least one property from second area 8b. In this embodiment, reinforcement band structures 7d, 7e and 7f may for example have a higher loop density and/or a higher filament crossing density and/or a higher crossing number along each loop than second area 8b. for example a lower loop density in region 8b allows for a better breathability and thus increases the wearing comfort. To further increase breathability and also decrease the overall weight of shoe 100, upper 4 further defines cut-out 15. Reinforcement band structures 7d, 7e and 7f are arranged at optimized positions. For example, reinforcement band structure 7d extends from the lateral side to the medial side over heel edge 11. In the worn state, reinforcement band structure 7d thus surrounds the Achilles tendon of the wearer. Providing a reinforcement band structure at this positions allows to fit the upper and the shoe tightly to the wearer's foot. Reinforcement band structure 7e extends linearly on the medial side of upper 4 and provides an increased resistance, for example abrasion resistance. Reinforcement band structure 7f is arranged in the peripheral bottom section of the upper and in the forefoot area and extends along connection area 9 on the lateral and medial side over tip 10. In particular on the lateral side, such a reinforcement band structure is beneficial, because when a wearer runs along a curve this area is particularly strained.

FIG. 6 shows a microscopic image of a section of a textile sheet product, which shows thermoplastic filament 8 forming loops and crossings, such as crossing c1 at which the thermoplastic filament crosses itself and form a material-bonded connection with itself. Furthermore, it can be seen that the thermoplastic filament, respectively the loops, define rhombic openings 14 which penetrate through the textile sheet product. In addition, fused bulge portion 12 is formed by adjacent fusion of two filament sections.

FIG. 7 shows another microscopic image of a textile sheet product 1 forming a plurality of loops along a filament path. The image has a smaller magnification than the image shown in FIG. 6.

FIG. 8 shows an enlarged section of a microscopic image of a textile sheet product according to an embodiment of the invention. In the image 8 crossings formed by the thermoplastic filament 2 are shown. For example, it can be seen that crossing c1 is formed by a lower filament section upon which an upper filament section of thermoplastic filament 2 is arranged.

FIG. 9 shows a microscopic image of a textile sheet product according to another embodiment of the invention. It can be seen that the thermoplastic filament forms a plurality of loops along a filament path. Similar to the embodiment shown in FIG. 2, the filament path overlaps itself. A first section of the filament path (in this case the top row) is arranged on top of a second section of the filament path (in this case the bottom row).

FIG. 10 shows another microscopic image of a textile sheet product according to another embodiment of the invention, in which the thermoplastic filament forms fused bulge portion 12. As can be seen, two filament sections 13a and 13b of the thermoplastic filament 2 which each form a loop merge together at fused bulge portion 12.

TEXTILE SHEET PRODUCT

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