Not applicable.
The invention relates to a shoulder pad assembly worn by a player in a contact sport, such as football, lacrosse or hockey. The shoulder pad is formed from a novel, high-strength, low weight material and includes a fastening assembly for connection of a side pad assembly, an energy attenuation system for dissipating an impact force, and an integrated interior pad assembly.
In most contact sports, the players are required to wear an assortment of protective gear, including shoulder pads, to reduce the occurrence of injury. For example, conventional football shoulder pads are bilaterally symmetrical and are generally comprised of right and left body arch members which extend over the shoulders and include anterior and posterior portions, or depending chest and back portions, which overlie the chest and back of the athlete. The posterior portions, or depending back portions may be permanently hinged together along a vertical axis over the athlete's back or spine, while the anterior portion, or depending chest portions, are connected together on a vertical line over the athlete's sternum as by means of straps or lacing.
A side pad assembly, comprising an epaulet and a shoulder cap, is rigidly linked by multiple connectors to the body arch member. The side pad assembly protects the player's shoulder wherein a portion of the body arch member overlies the acromioclavicular area (the “A.C.” area), which includes the clavicle and the acromion, where the latter is the lateral extension of the spine of the scapula. In general, the A.C. area of the shoulder extends from the base of the neck downwardly towards the tip of the shoulder, or deltoid muscle. With conventional shoulder pad designs, the epaulet is pivotally connected to the arch member by a first strap and the shoulder cap is pivotally connected to the arch member by a second strap, wherein the epaulet overlies the shoulder cap. Due to the rigid connection provided by the straps, the range of motion of the side pad assembly is limited and the overall comfort of the shoulder pad is affected. The structural members, such as the body arch members, the shoulder caps and the epaulets, are manufactured from a material having the requisite strength characteristics to withstand the forces of impact incurred while playing contact sport. Conventional shoulder pads may also include a strap of material which has its ends fixedly secured to the body arch member, as by rivets or other suitable connectors. Typically, these straps are referred to as cantilever straps, and they support the body arch members in a spaced relationship from the pad body, as well as from the shoulder of the player.
Unlike football shoulder pads which include two distinct pads, the epaulet and the cap, which overlie the player's shoulder for protection thereof, conventional hockey and lacrosse pads feature only the shoulder cap. Hockey and lacrosse pads do not include the additional epaulet for a number of reasons, including the oversized configuration of the cap, the lower profile of the shoulder pads, and the reduced level of contact in these sports compared to football.
Existing shoulder pads also utilize a number of distinct interior pads disposed beneath the body arch members, wherein the interior pads are either fixedly secured, or releasably secured, to the body arch members. By using a number of distinct interior pads to form the interior pad elements, the construction of the shoulder pad and the fit of the shoulder pad can be affected.
Therefore, there is a definite need for a shoulder pad with a fastening assembly for the side pad assembly that does not inhibit the range of motion or comfort of the pad assembly. Further, there is a tangible need for an integrated interior pad assembly that can be quickly and easily joined to the arch members during the construction of the shoulder pad. There is also a tangible need for a lighter shoulder pad that maintains the required strength and durability.
The present invention is provided to solve the problems discussed above and other problems, and to provide advantages and aspects not provided by prior shoulder pads.
The present invention relates to a shoulder pad that is to be worn by a participant of a contact sport, such as football, hockey or lacrosse. The shoulder pad includes a first body arch member, a second body arch member, a left side pad assembly flexibly connected to the left body arch member, and a right side pad assembly flexibly connected to the right body arch member. The shoulder pad further includes a left interior pad assembly removably affixed to the left body arch member and a right interior pad assembly removably affixed to the right body arch member.
According to one aspect of the invention, each side pad assembly includes an epaulet and an attached interior pad, and a shoulder cap and an attached interior pad. The arch members, the epaulets, and the shoulder caps are made of a material having the requisite strength and rigidity requirements to withstand the forces of impact incurred in the contact sport. Each side pad assembly is affixed to the upper portion of the body arch member by a fastening assembly that comprises a single flexible band and at least one rivet. Unlike conventional shoulder pad designs, the single band connects both the epaulet and the shoulder cap to the body arch member. The band has a first end that is affixed to the upper portion of the body arch member by a securing plate and at least one rivet that is driven therethrough. The band has an intermediate portion between the first end and a second end, wherein the intermediate portion is affixed to an inner surface of the epaulet by at least one rivet. The second end of the band is affixed to an inner surface of the shoulder cap by at least one rivet. Thus, a single flexible band is utilized to connect both the epaulet and the shoulder cap to the body arch member while providing a greater range of motion to the side pad assembly.
According to another aspect of the invention, the shoulder pad assembly includes an impact distribution and energy attenuation system that distributes and reduces an impact force throughout the pad assembly. As part of the system, the arch member has a raised segment that is aligned and cooperatively dimensioned with a raised segment of the shoulder cap. Furthermore, the epaulet has a raised segment that is aligned and cooperatively dimensioned with the other raised segments. The raised segments collectively define a channel that distributes and attenuates the force of impact received on the side pad assembly.
According to yet another aspect of the invention, the left and right interior pad assemblies comprise a number of distinct pads joined as an integrated padding unit. The interior pad assembly comprises a number of pads—a front pad, an intermediate pad, and a rear pad—joined to form distinct air management chambers. The pad element is formed from open-cell foam or closed-cell foam, or a combination thereof. The interior pad assembly may include a deltoid pad, wherein the deltoid pad extends from a portion of the front and intermediate pads. A front region of the interior pad assembly includes means for securing the pad assembly to the front portion of the body arch. Similarly, a rear region of the interior pad assembly includes means for securing the pad assembly to the rear portion of the body arch.
According to yet another aspect of the invention, the structural members, such as the body arch members, the shoulder caps and the epaulets, is fabricated from a novel consolidated polymer fiber fabric material providing increased material strength characteristics while decreasing the weight of the structural members which results in a lighter and stronger pad assembly.
Compared to conventional shoulder pads, the present invention provides a number of advantages. The fastening assembly that secures the side pad assembly to the body arch member provides a greater amount of mobility for the side pad assembly with respect to the arch member. In addition, the fastening assembly comprises few parts, primarily the single band, and is easily installed on the shoulder pad thereby reducing both material and assembly costs. The raised segments of the arch member, the shoulder cap, and the epaulet form the distribution and energy attenuation system that distributes and generally reduces an impact force throughout the pad assembly. Regarding the integrated interior pad assembly, combining multiple pads into a single pad assembly provides for more efficient air management upon an impact to the shoulder pad. The novel thermoplastic composite material provides for a stronger and lighter pad assembly providing additional protection while reducing the strain on the participant. Furthermore, due to the integrated construction of the interior pad assembly, the shoulder pad is more comfortable for the participant to wear while playing the contact sport.
Other features and advantages of the invention will be apparent from the following specification taken in conjunction with the following drawings.
While this invention is susceptible of embodiments in many different forms, there is shown in the drawings and will herein be described in detail preferred embodiments of the invention with the understanding that the present disclosure is to be considered as an exemplification of the principles of the invention and is not intended to limit the broad aspect of the invention to the embodiments illustrated.
A shoulder pad assembly 10 is shown in FIGS. 1 and 4-7. The shoulder pad 10 is configured to be worn by a participant of a contact sport, such as football, hockey or lacrosse. The shoulder pad 10 includes a first or left body arch member 20, a second or right body arch member 22, a left side pad assembly 24 flexibly connected to the left body arch member 20, and a right side pad assembly 26 flexibly connected to the right body arch member 22. A central body 21 is defined by the left and right body arch members 20, 22 which are operably joined to form the central body 21. Each of the side pad assemblies 24, 26 are configured to overlie a shoulder region of the wearer. The shoulder pad assembly 10 further includes a left interior pad assembly 28 removably affixed by fastening means 104 (see
Each body arch member 20, 22 includes an upper portion 32, 34, a front or chest portion 36, 38 depending from the upper portion 32, 34, and a rear or back portion 40, 42 depending from the upper portion 32, 34. Thus, the arch member 20, 22 is a single piece that extends between the wearer's lower chest region and lower back region. As shown in
As shown in FIGS. 1 and 4-7, the side pad assembly 24, 26 includes an epaulet protective element 60 and an attached interior pad 62, and a shoulder cap protective element 64 and an attached interior pad 66. Preferably, the interior pads 62, 66 are attached to the epaulet 60 and the shoulder cap 64, respectively, by at least one rivet 51 (see
Referring to FIGS. 1 and 4-7, each side pad assembly 24, 26 is affixed to the upper portion 32, 34 of the body arch member 20, 22 by a fastening assembly 68 that comprises a single flexible band 70 and a plurality of rivets 72. The band 70 can be operably connected to either an upper surface or a lower surface of the body arch member 20, 22. The band 70 provides a common connection point on the arch member 20, 22 for both the epaulet 60 and the shoulder cap 64. The band 70 has a first end 74 that is affixed to the upper portion 32, 34 by a securing plate 76 and at least one rivet 72 that is driven therethrough. Alternatively, the securing plate 76 is omitted and the rivet 72 extends through the first end 74 of the band 70 and the arch member 20, 22. The rivet 72 can include a protective sheath 73 (see
The side pad assembly 24, 26 is shown in an elevated position in
As explained above, the band 70 of the fastening assembly 68 extends from the upper region 32, 34 of the arch member 20, 22 and away from the central opening 50 to flexibly secure the side pad assembly 24, 26 to the respective arch member 20, 22. As a result, the fastening assembly 68 provides a single linked attachment between the side pad assembly 24, 26 and the arch members 20, 22. Described in a different manner, the fastening assembly 68 provides for pivotal movement of the entire side pad assembly 24, 26 about the connection point when an upwardly directed force is applied thereto. Said upward force can result from the wearer raising an arm to throw or catch an object, such as a football. As an example, when the upwardly directed force is applied to the epaulet 60, both the epaulet 60 and the shoulder cap 64 pivot about the connection point on the arch member 22, 24.
Unlike the shoulder pad 10 of the present invention, conventional football shoulder pads typically utilize multiple straps and connectors to fasten the side pad assembly to the arch members.
In contrast to conventional designs and as schematically shown in
Compared to conventional devices for securing side pad assemblies to arch members, the fastening assembly 68 of the present invention provides a number of benefits. Primarily, the fastening assembly 68, through the use of the single band 70, provides a greater amount of mobility for the side pad assembly 24, 26 with respect to the arch member 20, 22. As a result, the restrictions placed on the range of movement by conventional devices are not found in the present invention. In addition, when an impact is absorbed by the side pad assembly 24, 26, the fastening assembly 68 helps to maintain the proper positioning of the shoulder pad 10 on the player. Furthermore, the fastening assembly 68 comprises few parts, including the single band 70, and is easily installed on the shoulder pad 10 thereby reducing both material and assembly costs.
The shoulder pad assembly 10 also includes an impact distribution and energy attenuation system 150 that is adapted to distribute an impact force throughout the pad assembly 10. Referring to FIGS. 1 and 4-6, the system 150 includes an upper raised arch segment 152, a front raised arch segment 154, and a rear raised arch segment 156. As shown in
Referring to
When the shoulder pad assembly 10 is worn by a participant in a contact sport, e.g. football, hockey or lacrosse, the impact distribution and energy attenuation system 150 distributes and attenuates an impact force received on the side pad assembly 24, 26 in a controlled manner. An impact force is transferred through the side pad assembly 24, 26 and the arch member 20, 22. However, the system 150 prevents that force from being transferred to the wearer's acromioclavicular area (A.C. area) because the raised segments 152, 158 that overlie that area resist compression. Due to the corrugation that the raised segments 152-158 provide and under normal impact forces experienced during contact sports, the channel 162 does not compress and therefore does not engage the wearer's A.C. area. The channel's 162 lack of compression and engagement prevents the impact force from being transferred to the wearer's A.C. area. While the channel 162 resists compression and engagement with the A.C. area, the un-raised portions of the arch member 20, 22 and the shoulder cap 62 compress an amount to engage the wearer's non-A.C. area and transfer the impact force thereto. It is understood that the side pad assembly 24, 26 and the arch members 20, 22 absorb a significant amount of energy thereby reducing the impact force transferred to the wearer.
Referring now to
The interior pad assembly 28, 30 further includes a first removable pad 98 and a second removable pad 100, wherein each pad 98, 100 is removably received by the intermediate pad 94 with a hook and loop (Velcro™) fastener. When the pad assembly 28, 30 is installed in the shoulder pad 10, the first and second removable pads 98, 100 are positioned proximate the upper portion 32, 34 of the arch member 20, 22. The intermediate pad 94 has a inner comfort edge 102 that helps to prevent chafing with the player's torso region. The front pad 90 includes means for fastening 104 the pad 90 to the front portion 36, 38 of the body arch 20, 22. Similarly, the rear pad 92 includes means for fastening 104 the pad 92 to the rear portion 40, 42 of the body arch 20, The fastening means 104 is affixed to an inner surface 103 of the pad assembly 28, 30. The fastening means 104 can be a hook and loop (Velcro™) strap, a snap fastener, or a threaded fastener. As shown in
As mentioned above, the front, rear and intermediate pads 90, 92, 94 are joined to form a single, integrated pad assembly 28, 30. The front pad 90 is joined to the intermediate pad 94 at a front divider or seam 110, and the rear pad 92 is joined to the intermediate pad 94 at a rear divider or seam 112. Referring to
The resulting pad assembly 28, 30 has a length that corresponds to the length of the body arch 20, 22 thereby providing an integrated padding element for the body arch 20, 22 with multiple air management chambers. Combining and integrating multiple pads 90, 92, 94 as a single pad assembly 28, 30 permits the pad assembly 28, 30 to be easily installed to the arch member 20, 22 compared to the piecemeal installation required by conventional multiple inner pads. As a result, the material and assembly costs of the shoulder pad 10 are lowered. Furthermore, due to the integrated construction of the pad assembly 28, 30, the shoulder pad 10 is more comfortable for the participant to wear while playing the contact sport.
In another embodiment of the present invention, components of the shoulder pad 10, including the arch members 20, 22, the epaulets 60, and the shoulder caps 64 are made of a polymer fiber composite material that is formed from consolidated fabric layers and that has strength and weight properties not found in the materials used to form conventional pad assemblies. The inventive polymer fiber fabric composite comprises polyolefin fibers, such as polypropylene, and increases the ability of the arch members 20, 22, the epaulets 60, and the shoulder caps 64 to withstand the forces of impact incurred in the contact sport while decreasing the overall weight of the shoulder pad 10. The consolidated polymer fiber is a moldable fabric that can be used to make rigid sheets and/or formed into shoulder pad components that have a high stiffness-to-weight ratio and high impact resistance, even at low temperatures. The polymer fiber composite is comprised of a polyolefin tape yarn (often referred to as ribbon yarn), such polypropylene tape yarn, that is woven into a twill or “plain-weave” construction. Preferably, the polyolefin tape yarn is flat which makes it possible to achieve a weave and pattern that could not be accomplished with other types of round or substantially round yarns, however, tape yarn, due to its geometry, is more difficult to work with and achieve a perfect stitch. As explained below, the inventive polymer fiber composite material provides a significant improvement, for example two to fifteen times, in impact resistance over typical thermoplastics composites. Other advantages of the shoulder pad 10 formed from the polymer fiber composite material include its recyclability with existing recycling streams and because it is glass free, the polymer composite material is free from the safety and processing issues associated with glass-filled composites, namely skin irritation and increased tool wear.
The inventive polymer fiber fabric material includes material properties not previously associated with conventional materials used to form should pad assemblies. Table 1 provides material properties, measured under ASTM (American Society for Testing and Materials) standards, for a polypropylene composite, a type of polyolefin of the inventive polymer fiber composite. Bulk density, also referred to as the specific gravity or density of a solid, measures the mass of the material divided by the total volume occupied, where the total volume includes particle volume, inter-particle void volume and internal pore volume. Density is useful for calculating strength-weight and cost-weight ratios. Tensile modulus provides the ratio of stress to elastic strain in tension. A high tensile modulus means that the material is rigid—more stress is required to produce a given amount of strain—and reflects the ability of a material to resist breaking under tensile stress. Tensile strength represents the tensile stress at a specified elongation, where the maximum tensile strength is the highest tensile stress a material can support before failing under specific test conditions. Other tensile measurements include tensile strength at yield or at break. The tensile force (or stress) per unit area required to break a material in such a manner is the tensile strain to failure. Flexural strength of a material is defined as its ability to resist deformation under load, and represents the highest stress experienced within the material at its moment of rupture. Flexural modulus is the ratio of stress to strain in flexural deformation, or the tendency for a material to bend under an applied force. Heat deflection temperature is the temperature at which a polymer or plastic sample deforms under a specified load, and plays an important role, as it allows for manufacturers to monitor dimensional changes of the finished part with prescribed limits to achieve a faster molding process. Notched izod determines the impact strength of a specimen, where the specimen has a notch oriented towards the direction of impact, and also represents the energy lost per unit of specimen thickness at the notch. Gardner dart impact involves a test that measures the energy required to crack or break flat, rigid plastic specimens under various specified conditions of impact of a striker impacted by a falling weight. Coefficient of thermal expansion (CTE), α, is the dimensional response to a temperature change, and includes linear, area and volumetric components.
Table 2 provides a constant stiffness comparison of the polypropylene composite material to other common materials, some of which have been used to fabricate shoulder pads. To obtain a required stiffness of a part or article, the geometry, namely the thickness, of the polypropylene material can be reduced compared to a conventional material, as shown in the second column. The third column provides a percentage of weight savings offered by using the polypropylene composite material over the material listed in the first column. Thus, the polypropylene composite material allows for a thinner and lighter part compared to a second part having the same stiffness but formed from other materials. A part, for example the arch members 20, 22, formed from the polypropylene composite would be 53% thinner and 54% lighter than an arch member formed from HDPE material and having the same stiffness. In the context of football shoulder pads, the shoulder pad 10 formed from polymer fiber composites, including polypropylene, are thinner and lighter weight yet are as stiff as conventional pads.
Referring to Table 3 (below), the shoulder pad 10 formed from the polypropylene composite material (first row) has increased impact strength as evident by the Gardner Dart Impact test results for this material compared to other commonly used composite and plastic materials.
Two different methods can be employed with the polymer fiber composite material to fabricate the protective components of the pad assembly 10, including the arch members 20, 22, the epaulets 60, and the shoulder caps 64. Regardless of the molding method, the polymer fiber composite is fabricated from a tape yarn, such as a coextruded tape yarn, with a highly drawn core residing within a polymer matrix, which provides a lower melting point for composite processing. Under the first molding method, the tape yarn is woven into a fabric, and multiple layers of the fabric are stacked upon each other and then consolidated with heat and/or pressure to form a rigid sheet. The rigid sheet may then be cut into shapes and molded into the components of the pad assembly 10. Multiple sheets may be further consolidated into an assembly through the application of heat and/or pressure. In the second method, rather than stacking and consolidating the material into a sheet, the fabric layers may be stacked and consolidated directly in a mold of the components of the pad assembly 10 to form that particular component (e.g., arch members 20, 22). Stacking and consolidating the fabric layers directly in the mold does not require the production of large sheets of the material, and accordingly improves the efficiency of this method. In either method, the polymer fiber composite material is molded using pressure thermoforming techniques known to those in the art. The required pressure is between 10 and 20 bar, and the temperature window is 140° C. to 160° C. Convection heating or controllable infrared heat sources are preferred, but other methods may be used. Also, in either method the fabric layers or sheets may be constrained via clamping during the heating and molding process to prevent shrinkage. An additional advantage is that due to the polymer fiber composite's glass-free composition and relatively low pressure requirements, aluminum molds can be substituted for the traditional steel molds.
It is to be understood that the invention is not limited to the exact details of construction, operation, exact materials or embodiments shown and described, as obvious modifications and equivalents will be apparent to one skilled in the art; for example, the entire cantilever strap could be provided with a shock absorbing pad disposed upon its lower surface. Accordingly, the invention is therefore to be limited only by the scope of the appended claims. While the specific embodiments have been illustrated and described, numerous modifications come to mind without significantly departing from the spirit of the invention, and the scope of protection is only limited by the scope of the accompanying Claims.
This application claims priority from and is a continuation-in-part of prior U.S. application Ser. No. 12/381,554, filed Mar. 13, 2009 now U.S. Pat. No. 7,930,773, which is a continuation of U.S. application Ser. No. 11/224,493, filed Sep. 12, 2005, now U.S. Pat. No. 7,506,384, which claims the benefit of to U.S. Provisional Application No. 60/609,489, filed Sep. 13, 2004 which application is incorporated herein by reference and made a part hereof.
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Number | Date | Country | |
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Child | 12584896 | US |