The present invention relates to protective equipment, particularly but not exclusively for use in sports.
Athletes participating in certain sports wherein impact is common, such as hockey, lacrosse, and football, wear protective equipment in order to reduce the chance that they will be injured during the course of play. In ice hockey for example, a player typically wears several different protective garments, such as an upper-body protector, elbow guards, and shin guards. Each one of these protective garments incorporates one or more articles of protective equipment. For example, upper body protectors typically incorporate chest protectors, back protectors and shoulder caps. Shin guards typically incorporate both shin protectors and knee caps. Elbow protectors typically incorporate elbow caps.
A design common to such conventional commercial protective equipment is a polymeric energy absorbent core covered by a rigid non-deformable polymeric outer shell.
Protective equipment of this design provides players with good protection from impact injuries. Nonetheless, manufacturers of such equipment regularly consider new protective equipment designs that might provide improve protection.
It is an object of the present invention to provide protective equipment with a design that may provide good protection to certain players and/or in certain instances, in a sport such as ice hockey.
Thus, in one aspect, as embodied and broadly described herein, the present invention provides a user wearable article of protective equipment for protecting a portion of a body of the user. The article of protective equipment generally conforms to the portion of the body of the user to be protected when worn by the user. The article of protective equipment comprises an energy absorbent core. The core has a body-facing side and an opposing non-body-facing side. The core comprises a polymeric foam. The article of protective equipment also comprises an outer shell generally covering the non-body-facing side of the core. The outer shell is deformable during the use of the article of protective equipment by the user.
Without wishing to be bound by any particular theory, it is believed that protective equipment of the present design may provide better protection than current protective equipment of conventional designs for certain players of certain sports, particularly professional athletes such as professional ice hockey players. In particular it may be possible that because of the rigidity/non-deformability of the shells of protective equipment of conventional design, the force of an impact sustained by a player wearing such protective equipment is spread out across a much larger player body contact area than the actual area of the impact. This is because the shell does not substantially deform under such an impact and therefore the shell distributes the force of the impact across the shell's area of contact with the underlying core, which then distributes the force to the body of the player. Thus the player sustaining the impact effectively feels a smaller force over a larger area of their body (as compared with the same force over the smaller actual area of impact). For some, if not most, players, conventional protective equipment of this design provides them with good protection. However, for players at a very high or professional level of skill, the aforementioned force distribution effect may cause the player to believe that the player has sustained an impact of less force than they have, making them believe that they can sustain impacts of even greater force (be they with the boards or other players). Depending on the circumstances, this may not be desirable.
It is believed that by protective equipment of the present design being deformable (e.g. that flexes or distorts) in normal use when the player sustains an impact, that this will reduce the aforementioned phenomenon related to force distribution and will cause the player to effectively “feel” more of the force of the hit in the area in which they sustained the impact. This may allow the player to more accurately judge the force of the impacts they sustain, allowing them to more accurately control their actions and the effects of those actions during game play. In some embodiments, protective equipment of the present design will also reduce the aforementioned phenomenon by having an outer shell and an inner core that locally deform in the area that the player sustains an impact.
Non-limiting examples of polymeric foams of which the core may include are expanded polymer foams such as expanded polypropylene and expanded polyethylene. In some embodiments, the core is formed of expanded polymer foam that can repeatedly deform without breaking and/or permanently deforming.
In some embodiments, the core consists essentially of the polymeric foam. In the present context, this should be understood to mean that all of the material energy absorbing elements of the core are polymeric foam (whether a single foam or mixtures of multiple foams) and that the core contains no non-polymeric foam element that would materially affect the energy absorbent and force transmission of the core. In some embodiments, the core consists essentially of molded expanded polypropylene or expanded polyethylene.
As was noted above, the outer shell includes an elastomer, preferably elastomeric foam. In some embodiments, the elastomer is a polymer with a sufficient viscoelasticity such that, under normal use of the article of protective equipment into which the outer shell is incorporated, the outer shell will deform in the area of the shell which sustains and impact and will transmit a greater amount of the force of the impact to the area of the component of the protective equipment directly underneath the outer shell (at, or near, the point of impact) than would an outer shell made of a conventional rigid polymeric material (at least for some parts of the outer shell). Specific examples of elastomers suitable for use in the present invention are ethylene vinyl acetate foam and polyethylene foam.
In some embodiments, the outer shell consists essentially of an elastomer. In the present context, this should be understood to mean that all of the impact-sustaining elements of the outer shell are elastomeric (whether a single elastomer or mixtures of multiple elastomers) and that the outer shell contains no non-elastomeric element that would materially affect the flexing and force transmission of the outer shell. In some embodiments, the outer shell consists essentially of molded ethylene vinyl acetate foam or polyethylene foam.
In some embodiments, the article of protective equipment is generally free of non-deformable elements.
In some embodiments, the article of protective equipment is generally free of non-foam polymeric materials.
In some embodiments, the article of protective equipment is generally free of non-deformable polymeric materials.
In some embodiments, the article of protective equipment consists essentially of foam materials.
In some embodiments, the article of protective equipment consists essentially of expanded foam and elastomeric materials.
In some embodiments, the article of protective equipment consists of only one or more foams; stitching and/or adhesive; and, optionally, one or more fabrics and/or soft, flexible trims.
In some embodiments each of the elements of the article of protective equipment imparting structure to the article of protective equipment is deformable when the article of protective equipment is in use by the user.
In some embodiments, structural elements of polymeric materials of the article of protective equipment consist essentially of deformable polymeric materials.
In some embodiments, the protective equipment does not contain any structural elements having a durometer higher than about 70 (Shore A). For example, in some embodiments, all of the protective elements (e.g., shell(s), covering(s), and inner core(s)) have a durometer no higher than 70, 60, 50, 40, or no higher than 30 (Shore A). In certain embodiments, all of the protective elements have a durometer of about 30 to about 60 measured on the Shore A scale. For example, in certain specific embodiments, all of the protective elements have a durometer of about 35 to about 55 (Shore A).
In some embodiments, the article of protective equipment consists essentially of non-water-absorbent materials. By consisting essentially of non-water-absorbent materials, the protective equipment will not absorb water nor the sweat of the wearer, rending the protective equipment more conformable for longer periods of time, at least to some wearers.
In some embodiments, the core includes at least one reinforcement rib on the body-facing side thereof. Where included, such reinforcement ribs may be used for reinforcing the overall structure of the article of protective equipment, if such is required or desired. (The conventional rigid outer shell typically serves some structural function in conventional protective equipment articles. The absence of such a conventional rigid shell in embodiments of the present invention may mean that additional reinforcement may be required in some embodiments.) In some embodiments where at least one reinforcement rib is present, the at least one reinforcement rib may shaped to distribute a force of an impact around a joint of the user to be protected. Depending on the actual configuration of the equipment and particularly the reinforcement rib, it may be that it is the surface of the reinforcement rib that will actually contact the body of the wearer when the protective equipment sustains an impact. In such cases, the reinforcement rib may be structured so that the joint itself is not directly contacted by the surface the reinforcement rib during an impact. In some of such embodiments, the at least one reinforcement rib includes a circular portion encircling the joint. In some of such embodiments, the article of protective equipment further comprises a pad within the circular portion of the at least one reinforcement rib. The pad may be present to improve the comfort of the user and/or to provide additional protection to the user. Where present, the pad may be constructed of any suitable material serving its purpose. Examples include foams, gel packs, air packs, elastic materials, etc.
In some embodiments, the article of protective equipment further comprises an inner liner generally covering the body-facing side of the core. In some of such embodiments, the inner liner consists essentially of a deformable polymeric foam such as ethylene vinyl acetate or polyethylene foam. In some of such embodiments the inner liner consists essentially of ethylene vinyl acetate or polyethylene foam. In some of such embodiments, where present, the inner liner and the outer shell are directly secured together, encapsulating the core (i.e., the core is not directly secured to either the inner liner or the outer shell.) In other embodiments, the core is secured to the inner liner, the outer shell, or both. For example, the core can be secured to the inner liner, the outer shell, or both using an adhesive or stitching.
In some embodiments, the core is directly adjacent to the outer shell. In other embodiments, one or more deformable materials such as, for example, an additional foam layer may be positioned intermediate the core and outer shell.
In some embodiments the article of protective equipment is part of a protective garment. In some of such embodiments the garment is an upper-body protector and the article of protective equipment is a shoulder cap. In some of such embodiments the garment is an elbow protector and the article of protective equipment is an elbow cap. In some of such embodiments the garment is a shin guard and the article of protective equipment is a knee cap.
It should be understood that although generally described herein in terms of protective equipment for ice hockey, embodiments of protective equipment of the present invention can be used sports such as ice hockey, lacrosse, field hockey, football, baseball, softball, skateboarding, volleyball, skiing, snowboarding, BMX, inline skating, martial arts and other sports requiring shoulder, elbow, and/or knee protection. Also the embodiments of protective equipment of the present invention can have application in occupational safety e.g., construction, police, fire, etc.
Embodiments of the present invention each have at least one of the above-mentioned objects and/or aspects, but do not necessarily have all of them. It should be understood that some aspects of the present invention that have resulted from attempting to attain the above-mentioned objects may not satisfy these objects and/or may satisfy other objects not specifically recited herein.
Additional and/or alternative features, aspects, and advantages of embodiments of the present invention will become apparent from the following description, the accompanying drawings, and the appended claims.
For a better understanding of the present invention, as well as other aspects and further features thereof, reference is made to the following description which is to be used in conjunction with the accompanying drawings, where:
Referring to
Referring to
Referring to
The energy absorbent core 108 is a unitary structure made of molded expanded polypropylene, which is a polymeric foam. The energy absorbent core 108 has a body-facing side 118 (seen in
Within the circular section 124 of the reinforcing rib 122 is a pad 114. The pad 114 is provided for adding comfort to the wearer of the upper-body protector 100. The pad 114 is a unitary structure made of an open-cell polymeric foam and is sized and dimensioned to be snugly retained with the circular section 124 via a friction fit between its exterior circumference and the circular section 124 of the reinforcing rib 122. (The construction of the pad 114 is merely exemplary and will vary in other embodiments.)
Referring again to
Referring to
To form the right shoulder cap 102, each of the individual components (the absorbent core 108, the outer shell 110, the inner liner 112, and the pad 114) are separately manufactured (by conventional methods appropriate for the material of which the component(s) are constructed) and brought together in the appropriate alignment. As can been in
Once assembled the right shoulder cap 102 is used in the fabrication of the upper-body protector 100 in a conventional manner.
In this embodiment the left shoulder cap 104 is a mirror image of the right shoulder cap 102. In other embodiments the left shoulder cap need not be a mirror image of the right shoulder cap.
Referring to
Referring to
Modifications and improvements to the above-described embodiments of the present invention may become apparent to those skilled in the art. The foregoing description is intended to be exemplary rather than limiting. The scope of the present invention is therefore intended to be limited solely by the scope of the appended claims.
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2300774 | Sep 2001 | CA |
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Entry |
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Easton 06 Hockey catalogue. |
Easton Stealth S9 Shoulder Pad Hang Tag; eastonhockey.com. |
Number | Date | Country | |
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20130167291 A1 | Jul 2013 | US |