The present disclosure relates generally to protective devices for skates and, more particularly, to a removable skate shield that is mountable to a boot portion of an ice skate.
This section provides background information related to the present disclosure which is not necessarily prior art.
Due to the nature of the game, ice hockey injuries are common and range from annoying aches and pains to more serious traumas. Statistics indicate that a large majority of ice hockey injuries are caused by direct trauma during games. Hard body checks, player collisions with each other and the sideboards or ice, and direct blows from the puck, flying sticks and skates are the most common cause of such injuries. To this end, hockey players wear safety equipment such as helmets, pads and protective gear to avoid or reduce the risk of injury.
Skate protectors are used by hockey players in an effort to reduce the occurrence of foot injuries due to impact forces applied to their skates. Typically, skate protectors include multi-piece assemblies that are tied-on or strapped to the ice skates. Due to the excessive time required to install and remove conventional skate protectors, use of such protective devices has met with only minimal success. Examples of known skate protectors are disclosed in U.S. Pat. No. 2,029,787 to Ohler; U.S. Pat. No. 3,806,145 to Czeiszperger; U.S. Pat. No. 5,234,230 to Crane; U.S. Pat. No. 5,829,170 to Lutz; U.S. Pat. No. 6,854,200 to Hipp; U.S. Pat. No. 7,021,663 to Moran; U.S. Pat. No. 7,253,567 to McClelland; and U.S. Pat. No. 8,109,013 to Parrott.
In view of the shortcomings associated with such conventional skate protectors, a need exists to develop improved protective devices that provide enhanced foot protection and simplified use.
This section provides a general summary of the disclosure and is not a comprehensive disclosure of its full scope or all of its features.
It is an aspect of the present disclosure to provide a skate shield that addresses and overcomes the shortcomings of conventional skate protectors.
It is another aspect of the present disclosure to provide a skate shield having a shell made from a fiber reinforced polymer or plastic (FRP) material capable of providing enhanced stiffness while functioning to distribute impact forces over a larger area of the foot.
It is another aspect of the present disclosure to provide a skate shield that can be easily and quickly installed and removed from ice skates.
These and other aspects are provided by a skate shield constructed in accordance with the teachings of the present disclosure. Specifically, the skate shield includes a shell fabricated from a fiber reinforced material and configured to include a medial side portion and a lateral side portion interconnected by a top portion. A toe aperture formed in a front end of the top portion surrounds a toe portion of the ice skate, an ankle aperture formed between the medial and lateral side portions and a back end of the top portion surrounds an ankle portion of the ice skate, and a heel aperture communicating with the ankle aperture surrounds a heel portion of the ice skate. The skate shield further includes a fastener assembly adapted to releasably interconnect the medial side portion and the lateral side portion across the heel aperture for removably securing the shell to the ice skate.
The fastener assembly associated with the skate shield of the present disclosure may include a strap having a first end portion rigidly affixed to one of the medial and lateral side portions of the shell. A second end portion of the strap may be releasably secured to a fastener associated with the other one of the medial and lateral side portions of the shell. The fastener may include a hook and loop arrangement (VELCRO) a snap arrangement, or any other fastening arrangement configured to permit releasable attachment of the skate shield to the ice skate.
The fastener assembly associated with the skate shield of the present disclosure may alternatively include a pair of clip retainers rigidly affixed to each of the medial and lateral side portions of the shell and a resilient ring or strap that can be releasably secured to the clip retainers. The resilient ring can be configured as an O-ring sized to engage each of the clip retainers and permit releasable attachment of the skate shield to the ice skate.
The skate shield of the present disclosure further includes reinforced sections formed in at least one of the medial side portion, the lateral side portion and the top portion to provide additional shell thickness and rigidity. The reinforced sections include one or more reinforced sections which, in turn, each include one or more reinforcing layers laminated between an outer layer and an inner layer of the shell.
In accordance with another aspect of the present disclosure, a boot assembly of an ice skate is reinforced with one or more layers of a fiber reinforced material, oriented optimally to produce a stiff boot structure configured to protect critical areas of the foot. The reinforced boot assembly includes a rigid outer shell, a resilient/deformable inner shell, and one or more layers of reinforcing material between the outer shell and inner shell. In this way, the reinforcement layers or “patches” can be integrated directly into the ice skate to provide an option to the ice skate and shield assembly of the present disclosure.
Further areas of applicability will become apparent from the description provided herein. The description and specific examples in this summary are intended for purposes of illustration only and are not intended to limit the scope of the present disclosure.
The drawings described herein are provided for the purpose of illustrating selected embodiments and are not intended to limit the scope of the present disclosure. In this regard, a detailed description of selected exemplary embodiments is provided herein with reference to the accompanying drawings.
Corresponding reference numerals indicate corresponding parts, components and/or assemblies throughout the several views of the drawings.
Example embodiments will now be more fully described with reference to the accompanying drawings. These example embodiments are provided so that this disclosure will be thorough, and will fully convey the scope to those who are skilled in the art. Numerous specific details are set forth such as examples of specific components, devices, and methods, to provide a thorough understanding of embodiments of the present disclosure. It will be apparent to those skilled in the art that specific details need not be employed, that example embodiments may be embodied in many different forms and that neither should be construed to limit the scope of the disclosure. In some example embodiments, well-known processes, well-known device structures, and well-known technologies are not described in detail.
In general, the present disclosure is directed to a skate shield that can be removably attached to a hockey skate for providing additional protection against foot and ankle injuries. As will be detailed with greater specificity, the skate shield of the present disclosure is preferably fabricated from a fiber-reinforced polymer or plastic (FRP) or thermoplastic (FRTP), such as a carbon-fiber cloth material, to provide a rigid, yet lightweight, protective device capable of use with virtually any type of conventional ice skate, roller skate or in-line roller skate.
As noted, the present disclosure relates to skate shields for use in cooperation with skates, particularly ice hockey skates, for providing additional protection to the foot and ankle of a skater. To better define the areas afforded additional protection,
Referring now to
Inner liner 20 is secured to an inner surface of outer shell 12 and has an elongated tab 32. Inner liner 20 is configured to contact several portions of foot (F) including heel (H), ankle (A), medial side (MS) and lateral side (LS). Footbed 22 is also mounted inside outer shell 12 and includes a surface 34 configured to receive the plantar surface (PS) and a pair of side surfaces 36 partially surrounding the sides of foot (F).
The boot assembly (BA) further includes a pair of bands 38 secured to side portions of outer shell 12. Bands 38 include apertures 40 which receive eyelets 42 that also extend through apertures 44 formed in outer shell 12. A tendon guard 46 is also affixed to outer shell 12 to overlay tab 32 of inner liner 20 and is configured to face at least a portion of upper portion (UP) of Achilles tendon (AT). Outer shell 12 is configured to include an enclosed heel portion 48 for receiving heel (H), an ankle portion 50 for receiving ankle (A), and medial and lateral side portions 52, 54 for facing the medial and lateral sides (MS, LS), respectively.
Referring now to
Skate shield 100 is shown to generally include a rigid shell 152 having a medial side portion 102 and a lateral side portion 104 interconnected by a top portion 106. Skate shield 100 also includes a strap-type fastener assembly 108 for releasably securing rigid shell 152 on the boot assembly (BA) of ice skate 1. Medial side portion 102, lateral side portion 104 and top portion 106 cooperate to define an ankle opening 110 configured to generally surround ankle portion 50 of outer shell 12.
Medial side portion 102 is shown to include a medial side section 112, a bottom flange section 114 extending transversely from medial side section 112, and a heel flange 116 extending transversely from medial side section 112. Preferably, bottom flange section 114 and heel flange section 116 define a continuous flange adapted to engage corresponding medial portions of the boot assembly (BA). Specifically, bottom flange section 114 is configured to surround and overlay a medial portion of outsole plate 26 while heel flange section 116 is configured to surround and overlay a medial part of heel portion 48 of outer shell 12. In addition, medial side section 112 includes at least one reinforced section 118 (shown in phantom) which is shown, for example, to be configured to be aligned with and overlay ankle portion 50 and medial side portion 52 of outer shell 12.
Lateral side portion 104 is shown to include a lateral side section 122, a bottom flange section 124 extending transversely from lateral side section 122, and a heel flange section 126 extending transversely from lateral side section 122. Preferably, bottom flange section 124 and heel flange section 126 define a continuous flange adapted to engage corresponding lateral portions of the boot assembly. Specifically, bottom flange section 124 is configured to surround and overlay a lateral portion of outsole plate 26 while heel flange section 126 is configured to surround and overlay a lateral part of heel portion 48 of outer shell 12. In addition, lateral side section 122 includes at least one reinforced section 128 (shown in phantom) which is shown, for example, to be configured to aligned with and overlay lateral side portion 54 of outer shell 12.
Bottom flange sections 114 and 124 are generally aligned to extend along a common plane and are separated by an elongated bottom aperture 130 formed therebetween. Heel flange sections 116 and 126 are likewise generally aligned to extend along a common plane and are separated by a heel aperture 132. Heel aperture 132 communicates with bottom aperture 130 which, in turn, communicates with a toe aperture 134 formed in an open-end of top portion 106 of skate shield 100. Strap assembly 108 includes a strap 136 fixedly secured at a first end 138 (i.e. via rivets 140 or other suitable ‘fixed’ fasteners) to heel flange section 126 of lateral side portion 104. A second end 142 of strap 136 is releasably attachable (i.e. via snaps, Velcro or other suitable “releasable” fasteners) to heel flange section 116 and/or side section 112 of medial side portion 106. A recess 144 is formed in heel section 116 and side section 112 to retain second end 142 of strap 136 thereon. Obviously, the orientation of strap assembly 106 relative to the medial and lateral side portions of skate shield 100 can be reversed. When second end 142 of strap 136 is released from engagement, skate shield 100 may be easily slide on or off of ice skate 1. In contrast, when second end 142 of strap 136 is secured, skate shield 100 is mounted on ice skate 1.
A layer of an energy absorbing resilient material 150 is secured to the inner surface of medial side portion 102, lateral side portion 104 and top portion 106 to dampen the impact forces transferred from skate shield 100 to ice skate 1. Non-limiting examples of energy absorbing resilient material may include a layer of neoprene or foam that is bonded to the inside surfaces of skate shield 100 and which has a thickness in the range of 2-10 mm. The resilient layer of material 150 may be bonded as a single piece, such as to define an inner liner 151, or as separate pieces each bonded to corresponding portions of skate shield 100. The resilient layer 150 also functions to reduce damage to ice skate 1 due to contact with rigid skate shield 100. Additionally, resilient layer 150 provides a “gripping” function to maintain contact with the boot assembly (BA) of ice skate 1 and inhibit sliding movement between skate shield 100 and ice skate 1. Resilient layer 150 also provides a gripping surface for use by the user when installing skate shield 100 on ice skate 1.
In accordance with the present disclosure, a rigid shell 152 of skate shield 100 is defined by the combination of medial portion 102, lateral portion 104 and top portion 106. Shell 152 is preferably fabricated from a fiber reinforced polymer or plastic (FRP) or thermoplastic (FRTP) to provide a rigid, high-stiffness, component adapted to disburse impact forces prior to transmission of the impact forces to ice skate 1. More preferably, shell 152 is constructed from multiple layers of carbon fiber cloth that are bonded with a suitable resin to define a carbon fiber reinforced (CFR) component. Medial side portion 102, lateral side portion 104 and top portion 106 each include an outer layer 160 of carbon fiber cloth laminated to an inner layer 162 of carbon fiber cloth. Outer layer 160 can be made from, for example, a carbon fiber 12K 19 oz. 0.6 mm 2×2 twill cloth. Likewise, inner layer 162 can be made from, for example, a carbon fiber 12K 19 oz. 0.6 mm 2×2 twill cloth.
As best seen from
With shield 100 installed on ice skate 1, toe portion 14 extends through toe aperture 134 while its ankle portion extends through ankle aperture 110. In this manner, medial side portion 102 of shell 152 protects the medial side (MS) of the foot, lateral side portion 104 of shell 152 protects the lateral side (LS) of the foot, and top portion 106 of shell 152 protects upper surface (US) of the foot.
To mount skate shield 100 onto boot assembly (BA) of ice skate 1, the user twists one or both side portions 102, 104, generally upon gripping heel flange sections 116, 126, respectively. This twisting action creates sufficient enlargement of heel apertures 132 and ankle aperture 110 to permit shield 100 to slip over the boot assembly and past the user's ankle. Upon release of the twisted side portion(s), shield 100 returns to its original shape and strap assembly 108 is secured. One or more reduced thickness areas and/or holes, schematically and cumulatively shown in phantom by reference numeral 154, can be provided to assist in facilitating the twist movement of the side portions of skate shield 100. While alternative mounting techniques could be available, the high stiffness of the carbon fiber reinforced shell 152 tends to require use of this twisting type mounting technique. With shield 100 mounted on the boot assembly, bottom flange sections 114, 124 will engage outsole plate 26 and avoid interference with skate holder 28.
Referring now to
Skate shield 200 is generally shown in
To provide detailed illustrations and descriptions of the components associated with skate shield 200,
Medial side portion 202 of rigid shell 252 is shown to include a medial side section 212, a bottom flange section 214 extending transversely from medial side section 212, and a heel flange section 216 extending transversely from medial side section 212. Bottom flange section 214 and heel flange section 216 define a continuous flange adapted to engage corresponding medial portions of the boot assembly (BA). Specifically, bottom flange section 214 is configured to surround and overlay a medial portion of outsole plate 26 while heel flange section 216 is configured to surround and overlay a medial part of heel portion 48 of outer shell 12. Additionally, medial side section 212 includes at least one reinforced section 218 which is shown, for example, to be configured to be aligned with and overlay medial side portion 52 and ankle portion 50 of outer shell 12. As will be detailed, reinforced sections 218 include a plurality of reinforcing back plates 264.
Lateral side portion 204 is shown to include a lateral side section 222, a bottom flange section 224 extending transversely from lateral side section 222, and a heel flange section 226 extending transversely from lateral side section 222. Bottom flange section 224 and heel flange section 226 define a continuous flange adapted to engage corresponding lateral portions of the boot assembly (BA). Specifically, bottom flange section 224 is configured to surround and overlay a lateral portion of outsole plate 26 while heel flange section 226 is configured to surround and overlay a lateral part of heel portion 48 of outer shell 12. Additionally, lateral side section 222 includes at least one reinforced section 228 which is shown, for example, to be configured to be aligned with and overlay lateral side portion 54 and the lateral ankle portion of outer shell 12.
Bottom flange sections 214 and 224 are generally aligned and are separated by an elongated bottom aperture 230 formed therebetween. Heel flange sections 216 and 226 are likewise generally aligned and are separated by a heel aperture 232. Heel aperture 232 communicates with bottom aperture 230 which, in turn, communicates with a toe aperture 234 formed in an open-end of top portion 206 of rigid shell 252. Referring primarily to
Inner liner 251 is made from an energy absorbing resilient material and is secured to the inner surfaces of medial side portion 202, lateral side portion 204 and top portion 206 of shell 252 to dampen the impact forces transferred from skate shield 200 to ice skate 1 and the foot of the wearer. Similarly to liner 151 of skate shield 100, liner 251 can be made of any suitable material which may include, without limitation, neoprene or foam and which preferably has a thickness in the range of 2-10 mm. As shown in
In accordance with the present disclosure, rigid shell 252 of skate shield 200 is fabricated from a fiber reinforced polymer or plastic (FRP) or thermoplastic (FRTP) to provide a rigid high-stiffness, impact-resistant component. More preferably, shell 252 is constructed from at least two layers of carbon fiber cloth that are bonded with a suitable resin to define a carbon fiber reinforced (CFR) component. Shell 252 includes an outer layer 270 and an inner layer 272 each made from, for example, carbon fiber 19 oz. 12K 0.6 mm thick 2×2 twill cloth.
To mount skate shield 200 onto the boot assembly (BA) of ice skate 1, the user twists one or both side portions 202, 204 to expand heel aperture 232 and allow the ankle portion of boot 12 to extend into ankle aperture 210. Upon release, the deflected side portion(s) of shell 252 return to their original shape and ring-type fastener assembly 208 is thereafter secured.
While specific examples of skate shields 100, 200 have been disclosed with rigid shells fabricated from a least two layers of laminated carbon fiber reinforced material, it will be appreciated that other types of fiber reinforced material can likewise be used. These optional materials can include, for example, fiberglass and KEVLAR®. In addition, the weight, tow and weave of the fiber reinforced material can be selected to provide the requisite stiffness and manufacturability. Additionally, the matrix material used to bond the fiber reinforced layers can include any suitable polymeric resin, such as epoxy, to bind the cloth layers together. It is understood that any known method for laying and laminating the at least two layers may be used including hand laying, compression molding, and vacuum mold forming processes.
In summary, skate shields 100, 200 can be used by hockey players to reduce the occurrence of traumatic injury to the foot. Skate shields 100, 200 are constructed from at least two layers of a carbon fiber cloth bonded with a resin. Each layer is oriented to achieve maximum stiffness of shell 152, 252. This orientation may include parallel, orthogonal or any transverse alignment therebetween. The design of the rigid shell is configured to reduce the chance of a hockey stick getting caught between skate shield and ice skate 1. Weaker areas of the foot, or those prone to more severe trauma, may be reinforced with additional layers of reinforcing material.
Referring now to
Those skilled in the art will recognize that the carbon-fiber reinforced rigid shells of the skate shields disclosed herein can be fabricated from other materials providing the requisite rigidity and impact resistance. In addition, the rigid shells can be coated with an outer structural coating. This confirmation is shown in
The foregoing description of the embodiments has been provided for purposes of illustration and description. It is not intended to be exhaustive or to limit the disclosure. Individual elements or features of a particular embodiment are generally not limited to that particular embodiment, but, where applicable, are interchangeable and can be used in a selected embodiment, even if not specifically shown or described. The same may also be varied in many ways. Such variations are not to be regarded as a departure from the disclosure, and all such modifications are intended to be included within the scope of the disclosure.
This application claims priority to and the benefit of U.S. Provisional Application No. 61/858,242 filed Jul. 25, 2013 and U.S. Provisional Application No. 61/888,262 filed Oct. 8, 2013. The entire disclosure of the above applications is incorporated herein by reference.
Number | Date | Country | |
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61858242 | Jul 2013 | US | |
61888262 | Oct 2013 | US |