1. Field of the Invention
The present invention generally relates to footwear soles, and more particularly relates to footwear outsoles and tread constructions for footwear outsoles.
2. Related Art
According to the U.S. Bureau of Labor Statistics, slip and fall accidents are the second leading personal injury incident and second cause of accidental death in the United States. For the approximately 10 million work force in the food and preparation serving industry, as reported by the Bureau of Labor Statistics, these incidents represent about 65% of all lost time accidents among employees and more than 50% of all falls are caused by a slippery walking surface. By wearing footwear that includes slip resistant soles, some types of workers can minimize the risk of slip and fall accidents.
The slip resistance of a footwear can be tested using ASTM F1677-96 testing methods. These testing methods utilize the Brungraber Mark 11 testing, which applies both horizontal and vertical forces to a footwear sole simultaneously, resulting in a more thorough slip resistance measurement. These testing methods are well recognized throughout the United States and many other parts of the world.
The focus of the Brungraber testing is to measure the slip resistance of a footwear on dry, wet, and oily/wet surfaces. The tests are conducted on a 4-inch square section of American Olean red quarry tile as a test surface. To generate a slippery surface, testing labs use 0.05 grams (2 drops) of vegetable oil for the oily test. For the oily/wet test, 25 militers of water is added to the 0.05 grams of vegetable oil. A second test uses 0.2 grams (7 drops) of vegetable oil for the oily test with 25 militers of water added for the oily/wet testing. There are also dry tests and wet tests performed on the tile surface.
The slip resistance of a footwear can be affected by both the tread design and the materials of the footwear outsole. A footwear with improved slip resistant properties using tread design, materials, or a combination of tread design and materials would be an advance in the art.
The present invention generally relates to footwear outsoles and tread members for a footwear. One aspect of the invention relates to a footwear outsole that includes a base portion defining a tread attachment surface, and a plurality of tread members. The tread members are coupled to the tread attachment surface and protrude away from the tread attachment surface to define a tread member height. Each tread member includes a plurality of pointed arm members that extend away from a center portion of the tread member in a direction substantially parallel to a plane of the attachment surface. The arm members include a pointed tip that defines a maximum height of each tread member.
Another aspect of the invention relates to a footwear that includes an upper and an outsole coupled to the upper. The outsole includes an array of projections extending generally downward from the outsole. Each projection includes at least three pointed arms extending from a center portion of the projection in a direction substantially perpendicular to the direction in which the projection extends from the outsole. Each projection includes a downward facing primary surface defined in part by the pointed arms. The primary surface is configured to engage a ground surface and includes a recess formed therein.
A further aspect of the invention relates to a method of manufacturing a footwear sole. The method may include forming a base member that defines a mounting surface, forming a plurality of tread members, and coupling the tread members to the mounting surface. Each tread member includes a plurality of pointed arm members that extend from a center of the tread member in the plane of the mounting surface. The tread members may also include an outermost surface facing away from the mounting surface. The outermost surface includes a recess from tips of the pointed arm members toward a center of the tread member.
A still further aspect of the invention relates to a sole tread member that includes a base portion and a plurality of generally pointed arm members extending laterally from a center portion of the base portion. The base portion and arm members define an outward facing primary surface. The primary surface includes a recess and a plurality of edges that define a circumference of the recess.
Another aspect of the invention relates to a footwear outsole that includes a base portion defining a tread attachment surface, and a plurality of tread members coupled to the tread attachment surface. Each tread member includes a plurality of arm members that define a star shaped cross section. The cross section is taken in a direction parallel to a plane of the tread attachment surface. The tread members also include a primary surface facing away from the tread attachment surface. Each arm member includes a tip defined by an acute angle portion of the arm. The tips of the plurality of arm members defining a portion of the tread member extending furthest from the tread attachment surface.
A further aspect of the invention relates to a footwear outsole that includes a base portion having a tread attachment surface, and a plurality of tread members coupled to the tread attachment surface. Each tread member includes a plurality of pointed arms extending from a center portion of the tread member in a direction substantially perpendicular to the direction in which the tread member extends from the outsole. The plurality of tread members are positioned on the tread attachment surface at spaced apart locations from each other across an entire width of the base portion.
A still further aspect of the invention relates to a footwear outsole that includes a base portion defining a tread attachment surface, and a plurality of tread members coupled to the tread attachment surface. The tread members protrude away from the tread attachment surface, and each tread member includes a plurality of pointed arm members having an acute angle defining a point of each arm member. The tread members also include a recess formed in a primary surface of the tread member, the primary surface facing away from the tread attachment surface. The tread members may be aligned in diagonal rows relative to a longitudinal centerline of the outsole.
The above summary of the present invention is not intended to describe each disclosed embodiment or every implementation of the present invention. Figures in the detailed description that follow more particularly exemplify certain embodiments of the invention. While certain embodiments will be illustrated and describe embodiments of the invention, the invention is not limited to use in such embodiments.
While the invention is amenable to various modifications and alternate forms, specifics thereof have been shown by way of example and the drawings, and will be described in detail. It should be understood, however, that the intention is not to limit the invention to the particular embodiments described. On the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.
The present invention generally relates to footwear outsoles and tread constructions for footwear that provide improved slip resistant properties. An example tread construction according to the principles of the invention includes a plurality of tread members that protrude from a base member of the footwear outsole. The tread members include several pointed arm portions that extend laterally (a direction generally perpendicular from a direction in which the tread members protrude from the base member) from a center portion of the tread member to define a star-shape cross-section. The tread members also define a primary surface using the arm portions, wherein the primary surface faces generally downward and away from the base member of the footwear outsole. The aggregate primary surfaces of the plurality of tread members define a bottom surface of the footwear that has spaces between the tread members.
The arm portions of each tread member also define a plurality of edges and pointed tips that provide additional “gripping” of the tread members to a ground surface. The edges and pointed tips may be useful for directing fluid away from the tread member primary surface. The edges and pointed tips may also provide point and line contact areas between the footwear outsole and a ground surface that enhance the slip resistance of the footwear as compared to a surface contact between the ground surface and the footwear outsole.
The primary surface defined by each tread member may include a concave, cup-like shape that provides a “suction” effect that may further improve the slip resistance of the footwear. The tread constructions described herein may comprise a variety of different materials that also enhance the slip resistance of the footwear when combined with either or both of the star shapes and concave surface features of the tread construction.
The term “star shaped” as used herein is defined as any shape having at least two generally pointed arm portions that extend laterally outward from a center point. The resulting star shape may give the appearance of a multi-pointed star. Referring to
A concave and recessed surface as used herein is defined as any surface having a form that bulges inward. An example recessed surface resembles the interior of a portion of a sphere. Concave and recessed surfaces as used herein may include linear rather than curved portions. Preferably, concave and recessed surfaces as defined herein are any generally concave shaped surfaces that are recessed relative to a reference point such as a primary surface. A “footwear” as used herein is defined as any type of wear suitable for use on a foot such as, for example, a shoe, boot, sandal, overshoe, etc. The term “outsole” as used herein is defined as any layer or member of a footwear that defines in part an outermost bottom facing surface of a footwear.
Slip resistant tread constructions for footwear outsoles may include a plurality of tread projections having a circular, rectangular or triangular cross section. Each of these shaped tread members include several edges that define an edge length for the tread member. The tread members also typically define contact surfaces for contacting a ground surface. Further, when positioning several tread members relative to each other the tread members may define channels for directing fluids out from under the outsole or away from the contact surface. The tips and edges of the tread arms and the channel features may help improve the slip resistance of the tread construction.
An example footwear outsole 100 is shown and described with reference to
Other embodiments may include rows and columns of tread members that are aligned in parallel or perpendicular alignment with the axis 120, or at any diagonal angle desired. In further embodiments, the tread members may be aligned in curved rows or columns along the length or across a width of certain portions of the outsole. In yet further embodiments, the tread members may be positioned at random locations on the outsole rather than in rows or columns. Still further, the tread members of a single footwear may have many different sizes and shapes. For example, different tread sizes may be positioned to correspond with certain anatomical features of a user's foot.
Referring now to
The edges 140, 142 of each arm are shown coupled to each other as a continuous edge. The continuous periphery edge surface defined by the arms 132, 134, 136, 138 has a length that is greater than a periphery edge surface of a square-shaped tread member having four side edges that extend between corners of the square (see the dashed lines 151 in
The tread member 112 also includes a concave or recessed surface as shown in
The concave/recessed feature of the primary surface 146 may provide several advantages related to slip resistance. One advantage of the concave/recessed feature is that it isolates the tip 144 and edges 140, 142 vertically from the core 13. As a result, the first contact between a ground surface and the tread member 112 (the application of forces in the directions P and T shown in
The recess of the primary surface 146 may be recessed a depth of about 0.1 mm to about 2 mm, more preferably depth of about 0.1 mm to about 0.5 mm, and most preferably about 0.3 mm. The depth D of the recess is measured from an outer most point of the tread to the lowest depth of the recess (see
The number of tread members 112 on a give footwear outsole may vary. In one example, the outsole includes at least ten tread members in each of the forefoot and hindfoot portions 102, 106, an more preferably includes about 50 to 200 tread members in each of the forefoot and hindfoot portions 102, 106. In another example, the footwear outsole includes at least 100 tread members total.
Referring again to
In other embodiments, the sole member 100 may include only a few tread members that are clustered together at specific locations on the base portion 110 such as, for example, in discrete areas aligned with certain portions of a user's foot. In still further embodiments, individual star members may be positioned separately at desired locations across the base portion mounting surface 124 and may be combined with other tread member configurations and outsole features.
Referring now to
One difference between sole member 100 and sole member 200 is the shape of the forefoot and hindfoot sections 202, 206 and the size of the tread members 212 as compared to tread members 112. Another difference between sole member 100 and sole member 200 is the structure of the midfoot section 204 as compared to midfoot section 104. A still further difference between sole members 100, 200 is the structure of the base portion 210 that extends in a direction opposite the mounting surface 224. The differences between base portion 110 and base portion 210 illustrate that many different base portion configurations can be used in combination with the star shaped tread members 112, 212.
The sole features described above may be constructed using a variety of different method such as, for example, molding or casting. Different portions of the sole such as the tread members and the base portion of the sole that the tread members are secured to may be formed separately using any desired method or process and then later secured together using a connecting method such as, for example, adhesives or heat welding. In one embodiment, the base portion of the sole and the tread members are molded together in a single step using, for example, injection molding. In another embodiment, the tread members are molded onto the base portion or vice versa. The sole features described above may include different materials or combinations of materials to provide desired slip resistant properties. Some example materials includes natural rubber, synthetic rubber such as nitrile, styrene butandiene, and butyl, polyurethanes such as polyester and polyether, thermoplastic rubber, thermoplastic urethane, or combinations of these materials. In some embodiments, the tread members may include different materials than the base portion of the sole that the tread members are secured to. In other embodiments, the tread members themselves may includes different materials. For example, different tread members on a single footwear sole may include different materials to meet certain objectives for a specific portion of the sole (e.g., the heel strike area versa the forefoot area of the sole). In another example, a single tread member may include different layers of materials that are constructed by, for example, a layering molding process or by spraying a coating a layer onto a molded tread member.
The present invention should not be considered limited to the particular examples or materials described above, but rather should be understood to cover all aspects of the invention as fairly set out in the attached claims. Various modifications, equivalent processes, as well as numerous structures to which the present invention may be applicable will be readily apparent to those of skill in the art to which the present invention is directed upon review of the instant specification.
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