Running shoes can be constructed for multiple types of running environments and types of running. Often, road running shoes are constructed for running on pavement and other surfaces that are generally flat. These types of running shoes tend to be lightweight and flexible. Additionally, they include insulation to cushion or stabilize feet during repetitive strides on hard, even surfaces.
Trail-running shoes are often constructed for off-road routes that are rugged and include other obstacles such as puddles, mud, rocks, roots, and so forth. These shoes include aggressive treads for improved traction and are fortified to add stability and support. Generally, the outsole of the shoe extends substantially beyond the edges of the shoe's upper to provide the additional stability.
Cross-training shoes are constructed for workouts that include both aerobic and anaerobic types of activities. The soles of these shoes often have more contact with the ground to provide stability.
The shoe's upper construction also varies by the type of shoe. In some cases, the upper includes a synthetic leather that is durable and abrasion-resistant. This synthetic leather may be derived from nylon and polyester. The upper is generally lighter, dries faster and is more breathable than conventional leather. In other situations, the upper includes a nylon and/or nylon mesh that is durable and used to reduce weight and boost breathability. Another type of upper include a thermoplastic urethane overlay that is positioned over breathable panels of the shoe, such as panels in the arch and the heel. Also, conventional waterproof/breathable uppers use a membrane bonded to the interior of the upper's linings. This membrane blocks moisture from entering the shoe while allowing feet to breathe. Shoes with these membranes keep feet dry in wet environments with a trade-off in breathability.
One type of running shoe is disclosed in U.S. Patent Publication No. 2013/0340289 issued to Jean-noël Thevenoud. In this reference, a shoe includes an outer sole assembly and an upper, the shoe extending lengthwise from a rear end to a front end, widthwise between a lateral side and a medial side, and height-wise from the sole assembly to an upper end, the upper end demarcating a rear opening, the upper including a first envelope. The first envelope includes a rear portion, which itself includes a lateral wall, a rear wall and a medial wall, the rear portion being porous or having low resistance to the passage of a fluid. The first envelope includes a front portion, which itself includes a lateral wall, a front wall and a medial wall, the front portion being resistant to the passage of fluid or being impervious. A front portion of the first envelope of the upper include four layers. The first layer is a liner provided to contact the foot, as for the rear portion. The second layer is sandwiched between two other layers for added comfort, as for the rear portion. But here, differently, the lateral, front, and medial walls of the front portion include a waterproof layer. This layer is also sandwiched between two other layers. The layer is thin, or very thin, with a thickness of less than 1.0 mm, knowing that thicknesses of less than 0.2 mm have yielded good results. The waterproof layer is made, for example, of a film of synthetic material, such as polyethylene, polyamide, polyurethane, or any equivalent material. Optionally, the layer may be breathable and be waterproof. Finally, there is a protective layer, as for the rear portion. In the end, it is the entire portion that is made impervious by the waterproof layer.
In one embodiment, a running shoe includes a sole, an upper connected to the sole, a foot cavity defined at least in part with the upper, insulation incorporated into the upper adjacent to the foot cavity, and a waterproof fabric distally located with respect to the insulation and forming a protective exterior of the upper.
The running shoe may include a tongue connected to the upper, the tongue defining the foot cavity in part with the upper, and the waterproof fabric being incorporated in the tongue.
The waterproof fabric may be incorporated on an inside of the tongue.
The waterproof fabric that is incorporated into the tongue may be adjacent to the foot cavity.
The running shoe may include a tongue gusset that includes the tongue gusset defining the foot cavity in part with the upper and the tongue. The tongue gusset may include a first side connected to the tongue, a second side connected to the upper, an inside surface adjacent to the foot cavity, and the waterproof fabric forming the inside surface.
The waterproof fabric may be connected to the sole.
The waterproof fabric may have a characteristic of having a waterproof rating of at least 8,000 mm.
The waterproof fabric may have a characteristic of having a waterproof rating between 9,000 mm to 15,000 mm.
The waterproof fabric may include an air permeable membrane.
The waterproof fabric may include a polyurethane membrane.
The waterproof fabric may exhibit a first characteristic of transporting moisture across its thickness through a diffusive mass transfer mechanism.
The waterproof fabric may exhibit the first characteristic in addition to exhibiting a second characteristic of transporting moisture across its thickness through a convective mass transport mechanism.
In one embodiment, a running shoe includes a sole, an upper connected to the sole, a foot cavity defined at least in part with the upper, insulation incorporated into the upper adjacent to the foot cavity, a waterproof fabric distally located with respect to the insulation and forming a protective exterior of the upper, the waterproof fabric exhibits a first characteristic of transporting moisture across its thickness through a diffusive mass transfer mechanism, the waterproof fabric exhibits the first characteristic in addition to exhibiting a second characteristic of transporting moisture across its thickness through a convective mass transport mechanism, and the waterproof fabric exhibiting a third characteristic of having a waterproof rating between 8,000 mm to 15,000 mm.
The running shoe may include a tongue connected to the upper where the tongue defines the foot cavity in part with the upper and the waterproof fabric is incorporated in the tongue.
The waterproof fabric may be incorporated inside the tongue.
The waterproof fabric incorporated into the tongue may be adjacent to the foot cavity.
The running shoe may include a tongue gusset. The tongue gusset may define the foot cavity in part with the upper and the tongue. The tongue gusset may include a first side connected to the tongue, a second side connected to the upper, an inside surface adjacent to the foot cavity, and the waterproof fabric forming the inside surface.
The waterproof fabric may be connected to the sole.
The waterproof fabric may include an air permeable membrane.
In one embodiment, a running shoe includes a sole, an upper connected to the sole, a foot cavity defined at least in part with the upper, insulation incorporated into the upper adjacent to the foot cavity, a waterproof fabric distally located with respect to the insulation and forming a protective exterior of the upper, the waterproof fabric being connected to the sole, a tongue connected to the upper, the tongue defining the foot cavity in part with the upper, the waterproof fabric being incorporated in the tongue, the waterproof fabric is incorporated inside the tongue, the waterproof fabric incorporated into the tongue is adjacent to the foot cavity, a tongue gusset, and the tongue gusset defining the foot cavity in part with the upper and the tongue. The tongue gusset includes a first side connected to the tongue, a second side connected to the upper, an inside surface adjacent to the foot cavity, and the waterproof fabric forming the inside surface. The waterproof fabric includes an air permeable membrane. The air permeable membrane exhibits a first characteristic of transporting moisture across its thickness through a diffusive mass transfer mechanism, and the air permeable membrane exhibits the first characteristic in addition to exhibiting a second characteristic of transporting moisture across its thickness through a convective mass transport mechanism. The air permeable membrane exhibits a third characteristic of having a waterproof rating between 8,000 mm to 15,000 mm.
The accompanying drawings illustrate various embodiments of the present apparatus and are a part of the specification. The illustrated embodiments are merely examples of the present apparatus and do not limit the scope thereof.
Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements.
The foot cavity 106 may include a sock liner that lines the bottom of the foot cavity 106. Also, the side walls of the foot cavity 106 may include other types of cushioning that reduce the jarring impacts when the user's shoe strikes the running surface and holds the upper snuggly against the user's feet throughout the running motion. In some cases, the cushioning lines the entire surface of the foot cavity's wall. In other examples, the cushioning is a subset of the foot cavity 106.
In this example, the running shoe's upper 104 includes a low top profile 116 where the upper terminates underneath or at the user's ankle. The low top profile 116 provides the running shoe with a lower weight and provides the user additional movement.
The protective exterior 118 of the upper 104 is made of a waterproof fabric. In the example of
The air permeable membrane may exhibit a first characteristic of transporting moisture from within the shoe across the membrane's thickness through a diffusive mass transfer mechanism where the moisture build on the inside of the foot cavity causes the inside moisture to be transported across the air permeable membrane to equalize with the moisture concentration of the ambient environment outside of the foot. Additionally, the waterproof fabric exhibits a second characteristic of transporting moisture across its thickness through a convective mass transport mechanism. A convective mass transport mechanism includes transporting the inside moisture across the membrane with a gas carrier. In this case, the waterproof fabric can allow a small amount of air to pass through the waterproof fabric to accelerate the process of transporting moisture to the outside of the upper's protective exterior.
The waterproof fabric that forms the protective exterior also includes a second, convective water transport mechanism 808. The convective water transport mechanism 808 is enabled due to the waterproof fabric being air permeable such that a small amount of air passes through the waterproof fabric from the outside of the running shoe and then leaves back out of the shoe through the waterproof fabric. This additional air circulation accelerates the removal of water moisture inside the foot cavity or water moisture inside the upper's insulation in the inside layer. The lines schematically representing the convective water transport mechanism 808 are thicker than the lines schematically representing diffusive water transport mechanism to depict that more water moisture is removed from the convective water transport mechanism 808 than through the diffusive water transport mechanism 806.
In general, the invention disclosed herein may provide users with a running shoe that has a waterproof layer that allows moisture on the inside of the running shoe to leave. By placing the waterproof fabric of the running shoe on the outside of the upper, water is prevented from making contact with the other layers of the upper. For example, conventional running shoes that have a waterproof layer buried under a protective layer have the characteristic of absorbing water in the protective layer, which makes the running shoe heavier. The principles of the present invention incorporate the waterproof layer into the protective exterior so that the running shoe does not absorb water from outside of the running shoe.
Further, the principles described herein also include using an air permeable waterproof fabric. Conventional running shoes that incorporate a breathable, waterproof material generally rely on just a diffusive water transport mechanism. The diffusive water transport mechanism works based on diffusion and draws water moisture out of the shoe because the outside of the running shoe has a drier climate than in the foot cavity. The diffusive water transport mechanism thus requires that a water moisture content build up in the foot cavity of the shoe before the water diffuses to the outside of the shoe. For example, the user's foot has to be wet from sweat or have water enter another way before the sweat/water is transported out of the running shoe. The principles described herein include using a waterproof fabric that exhibits the additional characteristic of having an additional water transport mechanism, namely a convective water transport mechanism. The convective water transport mechanism is enabled by having the waterproof fabric be an air permeable material that allows more air to pass through the waterproof fabric than conventional waterproof materials, which are impermeable to wind. The additional air circulation in the waterproof material of the current system allows the moisture in the shoe to be removed at an accelerated rate without the foot cavity needing to have a moisture build up. In other words, the convective water transport mechanism occurs regardless of the amount of moisture content on the inside of the running shoe. Thus, the user's foot stays drier than with conventional running shoes with other kinds of waterproof materials. In some examples, the waterproof fabric has a lower waterproof rating than conventional waterproof materials to enable the air circulation. To enable the air circulation while maintaining a degree of waterproofness, the waterproof material may have a waterproof rating of 8,000 mm to 15,000 mm. Often, commercial materials that purport to be waterproof have a waterproof rating of over 25,000 mm. But, these running shoes suffer from the user's foot still being wet from the user's own sweat. Thus, the waterproof fabric of the present invention allows the user to have a drier foot despite having a lower waterproof rating.
The running shoe of the present system and method may include a sole that is made up of two distinct layers, the outsole and the midsole. The outsole may contact the ground. The outsole may be made of a hard, abrasion resistant material that resists wear, provides traction, and allows flexibility
The outsole may include a rubber compound with a high carbon content at the heel and in the toe box areas. The outsoles can be constructed with studs or ridges to provide traction on slippery surfaces, such as wet grass or slick pavement. In some examples, the outsole can include transverse grooves in the toe box area so that the running shoe is more flexible in the toe box area when the user's weight is loaded against the ball of the user's foot while the heel is raised off of the ground. Generally, the wider the outsole, the greater stability the outsole provides the foot. But, the wide outsole also increases the weight of the shoe. In some examples, the running shoe may include an outsole that is just as wider or has a width that is less than 5.0 percent greater than width of the corresponding sections of the shoe. Having a narrow outsole reduces the weight of the running shoe.
The midsole of the sole is located above the outsole. The midsole is made of a material that provides cushioning. The total height of the midsole and outsole under the heel may be about 1.0 inch and the total height of the midsole and outsole under the toe box is about 0.6 inches. The difference in sole thickness between the heel and toe box in can reduce the strain on the user's Achilles tendon. This drop in the height of the sole from the heel to the toe box may affect how the user's foot strikes the ground. In some cases, the heel drop may range from 4 mm to 10 mm. The running shoe's sole may be thicker than the soles of shoes that are intended for walking or other types of activities.
The midsole may be constructed of various materials to provide cushioning. In some cases, the midsole is made of ethyl vinyl acetate (EVA) or polyurethane. EVA is a copolymer of ethylene and vinyl acetate that has microscopic air bubbles within it that makes it lightweight while providing a good amount of cushioning. Polyurethane also has a microscopic air bubble structure like EVA but is generally firmer and more resistant to compression than EVA.
Conventional uppers are made of a combination of lightweight nylon to reduce the running shoe's weight. The upper of a running shoe may also incorporates a stiff heel counter that is commonly stiffer than in other athletic shoes to help control excessive pronation or supination during running.
Any appropriate type of running shoe may be used in accordance with the principles described herein. For example, the running shoe may include a low-top profile where the upper terminates just below the user's ankle. While a low-top upper may provide less lateral stability, the running shoe is lighter. In other examples, the running shoe includes a high-top profile. In this example, the running shoe includes an upper that extends over the user's ankle.
The waterproof fabric forms the protective exterior of the upper. This prevents water from entering the shoe through the upper. The tongue of the running shoe may also include a waterproof fabric. In some circumstances the waterproof fabric of the tongue has the same characteristics as the waterproof fabric incorporated into the upper. The waterproof fabric may be located on the underside of the tongue that is adjacent to the foot cavity, which is in contrast to the waterproof fabric of the upper that is located on the outside of the upper. The tongue may be connected to the upper along the tongue's edges with a gusset. The gusset may also be lined with the waterproof material. In some cases, the gusset's waterproof fabric is located on the inside surface that is adjacent to the foot cavity. In other examples, the gusset's waterproof fabric is located on the outside surface of the gusset.
In some cases, the waterproof fabric includes a water proof rating of 8,000 mm to 15,000 mm. A “mm” rating refers to the amount of rainfall a fabric can withstand in a single day. Thus a 10,000 mm waterproof rating means the garment can withstand 10,000 mm of rainfall in a single day without letting moisture in. The higher the number, the more waterproof the fabric is. Many commercially available waterproof materials have a waterproof rating of over 25,000 mm.
The pore size of the waterproof fabric disclosed herein is large enough to allow water vapor in the foot cavity and/or water vapor absorbed by the first layer to exit through the waterproof fabric. But, the pore size in the waterproof fabric is small enough to exclude water particles that would come from the ambient environment such as water from rain, mud puddles, or other sources. Thus, water can move from the inside of the shoe to the outside through a diffusive mechanism. The diffusive water transport mechanism allows some water to be removed from the inside of the running shoe or from the inside layers of the running shoe.
The waterproof fabric that forms the protective exterior also includes a second, convective water transport mechanism. The convective water transport mechanism is enabled due to the waterproof fabric being air permeable such that a small amount of air passes through the waterproof fabric. This additional air circulation accelerates the removal of water moisture inside the foot cavity or water moisture inside the upper's insulation in the inside layer. Convective mass transport works largely via advection or the transport of water through air motion. The convective mass transfer does not require sweat build up. The waterproof fabric can transport air out of the shoe when the user's foot is inserted into the shoe or not.
The types of water that can be transported out of the shoe include the user's sweat, but also includes the water that gets into the user's running shoe through other mechanisms. For example, if the user runs through a flowing creek during his or her run, water may spill over the edge of the running shoe's upper and into the foot cavity. This water may get absorbed into the insulation layer of the upper, the user's sock, or pool within the foot cavity. The air permeability may actively transport this water out of the upper's insulation and/or the user's sock. Water that is pooled may also be removed through the waterproof fabric's air permeable characteristics.
As noted above, conventional waterproof/breathable uppers use a membrane bonded to the interior of the upper's linings forming waterproof bootie inside the athletic shoe. This membrane blocks moisture from entering the shoe while allowing feet to breathe. Shoes with these membranes keep feet dry in wet environments with a trade-off in breathability. Additionally, the non-waterproof exterior portions of traditional shoes then absorbs water and become weighed down, even though the moisture may not reach the wearer. In contrast, the present exemplary system excludes moisture from entering the shoe and weighing down the shoe unnecessarily. Additionally, by placing the waterproof/breathable upper on the exterior of the shoe, a more rigid material may be used, which would be unsuitable for use as an interior liner of the shoe. This characteristic allows for the use of the breathable waterproof fabric disclosed above.
For the purposes of this disclosure, the term “air permeability” refers to the amount of air that flows through a fabric. Generally, as air flows through a fabric, cooler air from the ambient environment is exchanged with warmer air within the running shoe's foot cavity on the inside of the fabric. This air exchange lowers the temperature inside the foot cavity, but because the user's foot stays dry, the user feels like his or her feet stay warmer. Air permeability is the opposite of windproof and is not the same thing as breathability.
For the purposes of this disclosure, the term “breathable” refers to a fabrics ability to allow internal moisture to escape the fabric. This movement is determined by the difference in humidity between the foot cavity and the ambient air outside the fabric. The movement of the internal moisture is controlled, in part, by the physical resistance of the fabric layers. The humidity difference can be affected by a user's activity level, which induces sweating, and the humidity in the ambient environment. The physical resistance of the fabric generally increases with fabric thickness. Thus, thicker layers are generally have more resistance and breathe less.
A fabric's wind resistance is usually measured in miles per hour (mph) or cubic feet per minute (cfm). Most commercially waterproof/breathable rainwear fabric is is promoted as 100 percent windproof. In the current disclosure, the waterproof fabric is less than 100 percent windproof.
This application claims priority to U.S. Patent Application Ser. No. 62/287,347 titled “Waterproof Fabric in a Running Shoe” and filed on 26 Jan. 2016, which application is herein incorporated by reference for all that it discloses.
Number | Date | Country | |
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62287347 | Jan 2016 | US |