Protective sports helmet

Abstract

The present invention is directed to a protective sports helmet including a helmet shell, a face guard and an internal padding assembly positioned within the helmet shell. The internal padding assembly includes a brow pad having a first peripheral connection portion and a second peripheral connection portion. The internal padding assembly also includes a first jaw pad having an upper connection portion that mates with the first connection portion of the brow pad, and a second jaw pad having an upper connection portion that mates with the second connection portion of the brow pad. The internal padding assembly also includes a crown assembly with pad elements that include an internal separation layer that partitions the element into a first inflatable section and a second un-inflatable section. The connection portion of the jaw pads also mates with frontal pad elements of the crown assembly. The internal padding assembly further includes an occipital pad assembly that engages the helmet wearer's head below the occipital bone.

Description

TECHNICAL FIELD

The invention generally relates to a protective sports helmet, such as a football, lacrosse, hockey or baseball helmet, worn by a player during the play of a contact sport. The inventive helmet includes a number of improvements, including but not limited to a unique internal padding assembly that dissipates impact forces received by the helmet.

BACKGROUND OF THE INVENTION

Helmets for contact sports, such as those used in football, hockey and lacrosse, typically include a shell, an internal padding assembly, a faceguard or face mask, and a chin protector or strap that removably secures the helmet on the wearer's head. The internal padding assembly is secured to an interior surface of the shell to absorb a portion of energy received from a force applied to an exterior surface of the shell. Existing padding assemblies often include a plurality of padding elements that are arranged to contact a wearer's head when the helmet is worn.

Existing internal padding assemblies that are affixed to the inner surface of a football helmet often include a number of pad elements that may be formed from absorbent foam, air, gel or a combination thereof. Air may be utilized as an inflation fluid to adjust the dimensions of the pad element. An example of such a pad element is disclosed in U.S. Pat. No. 5,175,889. Another example of a helmet with an inflatable bladder is shown in U.S. Pat. No. 5,014,365. Conventional padding assemblies do not fully accommodate the anatomical distinctions among various wearer's heads, and under certain helmet impact conditions, these padding assemblies may not prevent the helmet from rotating about the wearer's head. This rotation may occur under a variety of conditions, including when the helmet's facemask is pulled, or when a player and/or helmet is subjected to a severe impact or a number of nearly simultaneous impacts.

The present invention is provided to solve these limitations and to provide advantages and aspects not provided by conventional sports helmets. A full discussion of the features and advantages of the present invention is deferred to the following detailed description, which proceeds with reference to the accompanying drawings.

SUMMARY OF THE INVENTION

The present invention is directed to a protective sports helmet that includes a number of improvements intended to increase the protective attributes of the helmet. For example, the helmet features an energy attenuating internal padding system with a face frame padding assembly comprising a brow pad and a pair of jaw pads that are cooperatively dimensioned and positioned within the helmet to frame the face of the wearer. The padding assembly also includes a unique crown pad element with an internal separation layer that partitions the pad element into a first inflatable section and a second un-inflatable section, which increases the stability of the helmet on the wearer's head. Additionally, the padding system assembly includes an occipital locking pad that contacts the occipital portion of the wearer's skull to resist forward and/or rearward rotation of the helmet when an impact(s) is applied to the helmet during the course of play of the contact sport.

While it is desirable that a protective sports helmet prevents injuries from occurring, it should be noted that due to the nature of contact sports (including football), no sports helmet, including the helmet of the present invention, can completely prevent injuries to those individuals playing sports. It should be further noted that no protective equipment can completely prevent injuries to a player, especially when the player uses the equipment improperly and/or employs poor form or technique. For example, if a football player uses the helmet in an improper manner, such as to butt, ram, or spear an opposing player (which is in violation of the rules of football), this can result in severe head and/or neck injuries, paralysis, or death to the football player, as well as possible injury to the football player's opponent. No football helmet, or protective helmet (such as that of the present invention) can prevent head, chin, or neck injuries a football player might receive while participating in the sport of football. The helmet of the present invention is believed to offer protection to football players, but it is believed that no helmet can, or will ever, totally and completely prevent injuries to football players.

Other features and advantages of the invention will be apparent from the following specification taken in conjunction with the following drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

To understand the present invention, it will now be described by way of example, with reference to the accompanying drawings in which:

FIG. 1 is a bottom view of an embodiment of an inventive sports helmet with internal padding assembly;

FIG. 2A is a sectional view taken through line 2-2 of the helmet of FIG. 1, including a wearer of the helmet being partially shown and padding elements of the padding assembly being shown in phantom lines;

FIG. 2B is a sectional view taken through line 2-2 of the helmet of FIG. 1, including padding elements of the padding assembly being shown in phantom lines;

FIG. 3 is a front view of a face frame padding assembly of the invention;

FIG. 4 is an exploded side view of the face frame padding assembly;

FIG. 5 is a rear view of the face frame padding assembly;

FIG. 6 is a top view of the face frame padding assembly;

FIG. 7 is a front view of a brow pad of the face frame padding assembly;

FIG. 8 is a sectional view of the brow pad taken through line 8-8 of FIG. 7;

FIG. 9 is a side view of a jaw pad of the face frame padding assembly;

FIG. 10 is a front view of the jaw pad of the face frame padding assembly;

FIG. 11 is a sectional view of the jaw pad taken through line 11-11 of FIG. 9;

FIG. 12 is a first side view of the jaw pad of the face frame padding assembly positioned within a padding liner;

FIG. 13 is an end side view of the jaw pad of the face frame padding assembly positioned within a padding liner;

FIG. 14 is a second side view of the jaw pad of the face frame padding assembly positioned within a padding liner;

FIG. 15 is a sectional view taken through line 15-15 of FIG. 14;

FIG. 16A is a view of a crown pad assembly, a side pad assembly, and an occipital pad assembly of the padding assembly;

FIG. 16B is a view of the crown pad assembly of the padding assembly;

FIG. 16C is a detailed view of an extent of the crown pad assembly of the padding assembly;

FIG. 16D is a view of the side pad assembly of the padding assembly;

FIG. 16E is a detailed view of an extent of the side pad assembly of the padding assembly;

FIG. 17 is a detailed view of a pad element of the crown pad assembly;

FIG. 18 is a sectional view of the pad element taken through line 18-18 of FIG. 17;

FIG. 19 is a detailed view of a pad element of the side pad assembly;

FIG. 20 is sectional view of the pad element taken through line 20-20 of FIG. 19;

FIG. 21 is a front view of the occipital pad of the padding assembly;

FIG. 22 is a sectional view of the occipital pad taken through line 22-22 of FIG. 21, showing the occipital pad in a deflated state; and,

FIG. 23 is a sectional view of the occipital pad taken through line 22-22 of FIG. 21, showing the occipital pad in an inflated state.

While the invention will be described in connection with the preferred embodiments shown herein, it will be understood that it is not intended to limit the invention to those embodiments. On the contrary, it is intended to cover all alternatives, modifications, and equivalents, as may be included within the spirit and scope of the invention as defined by the appended claims.

DETAILED DESCRIPTION

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.

In the Figures, a football helmet 10 in accordance with the present invention is shown and that includes: an outer shell 11, a faceguard 12, and an internal padding system 100. The helmet 10, the shell 11, and the faceguard 12 are substantially similar to those disclosed in U.S. patent application Ser. No. 13/068,104 filed on May 2, 2011 which is incorporated by reference herein in its entirety. The outer shell 11 is preferably made of any suitable plastic material having the requisite strength and durability characteristics to function as a football helmet, or other type of protective helmet, such as polycarbonate plastic materials, one of which is known as LEXAN®, as is known in the art. In the connected position shown in FIGS. 1-3, the faceguard 12 is positioned adjacent to a portion of an outer surface 18 of the shell 11. Referring to FIGS. 2A and B, the faceguard 12 covers a frontal opening 13 of the shell 11 that exposes the wearer's face 53, wherein the periphery of the frontal opening 13 is defined by a frontal jaw flap edge 11a, a front shell edge 11c and a lateral shell edge 11e that extends between the frontal jaw flap edge 11a and the front shell edge 11c. The frontal jaw flap edge 11a extends upward from a lower jaw flap edge 11f that is substantially linear. As shown in FIG. 2B, a rear lower edge 11b of the shell 11 extends between opposed lower jaw flap edges 11f, and includes a notch 11g that receives an extent of a strap member 205 of a chin protector assembly 200 when the helmet 10 is secured on the wearer's head 51. As shown in FIG. 2A, the chin protector assembly 200 includes a curvilinear cup member 210 that engages the wearer's chin 56c.

The Figures show an internal padding system 100 which is connected to an inner surface (or wall) 17 of the helmet 10. Preferably, the internal padding system 100 is releasably connected to the inner wall surface 17 by a plurality of connector means. Preferably the connectors means includes a hook and loop fastener assembly 136, which is generally referred to as a VELCRO® attachment, as by placing the hook and loop assembly on the internal padding system assembly 100 and the inner shell surface 17. The internal padding system 100 includes a face frame pad assembly 101 comprising a brow pad 102, a first jaw pad 104a, and a second jaw pad 104b that collectively define a frontal pad opening 16 (see FIG. 3). As shown in FIGS. 2A and 2B, the brow pad 102 resides within a partial liner 103 that leaves an upper, inner extent 102c of the brow pad 102 exposed and in direct contact with the inner surface of the shell 11. The internal padding system 100 further includes a crown pad assembly 110, a side pad assembly 112, and an occipital cradle pad assembly 114. In general, a pad assembly, such as the crown pad assembly 110, comprises a plurality of pad elements, wherein each pad element includes at least one pad member comprised of a pad material. As discussed below, two pad members can be combined to form a single pad element.

When the helmet 10 is worn, the brow pad 102 mates with the jaw pads 104 to enable the face frame pad assembly 101 to engage the frontal portion 52 of the wearer's head 51 while framing the wearer's face 53. The frontal head portion 52 includes the wearer's forehead 54 and the side regions depending downward there from to both sides of the wearer's jaw 56. Due to the mating of these components, the face frame pad assembly 101 provides continuous, interacting padding engagement between both of the wearer's jaws and across the forehead 54 (see FIGS. 2 and 3), meaning without an appreciable gap, interruption or discontinuity among the brow pad 102 and the jaw pads 104. In existing protective sports helmets with conventional internal padding assemblies, there is an appreciable gap, interruption or discontinuity because the brow pad and the jaw pads are separated by a considerable distance (e.g., at least 0.25 inch) that precludes continuous, interacting padding engagement. The brow pad 102 is configured to be positioned adjacent the wearer's brow and forehead 54, while the first and second jaw pads 104a, b are configured to be positioned adjacent the jaw 56 of the wearer 50. The brow pad 102 extends across the forehead 54 of the wearer 50, and between the temples 55 of the wearer 50. The first and second jaw pads 104a, b are substantially symmetric, wherein the first jaw pad 104a engages the right side of the wearer's jaw 56 and the second jaw pad 104b engages the left side of the wearer's jaw 56. The mating between the brow pad 102 and the jaw pad 104 provides an interconnection point 109 of the face frame assembly 101, wherein the interconnection point 109 is positioned above the front shell edge 11c, the shell ear opening 11d, and the wearer's eye 58 and ear 60 (see FIG. 2). The interconnection point 109 is preferably above a horizontal chord that is aligned with the front shell edge 11c and extends laterally there from to divide the shell 11 into upper and lower halves. The jaw pad 104 extends upward from the wearer's jaw 56, past the front shell edge 11c, the shell ear opening 11d and the wearer's eye 58 and ear 60, to the interconnection point 109 proximate the wearer's temple 55. Preferably, the interconnection point 109 is rearward or aft of the outer corner of the wearer's eye 58 (see FIG. 2). The interconnection between the brow pad 102 and the jaw pad 104 of the inventive helmet 10 differs significantly from the internal padding assemblies taught by the prior art. For example, U.S. Pat. No. 6,934,971 discloses a side pad assembly 125 with a sling 160 having an opening 161 that physically receives an upper pad member 151 of the jaw pad assembly 135 that is inserted into and through the opening 161 (see FIGS. 14 and 15). The '971 patent teaches that the insertion through the opening 161 is required to allow the pad member 151 to be suspended from the sling 160. In contrast, neither the brow pad 102 nor the jaw pad 104 are inserted through the other pad to form the interconnection point 109. Further, the '971 patent lacks any disclosure concerning the face frame pad assembly 101, including the mating between the brow pad 102 and the jaw pad 104 that leads to interconnection, the location of said interconnection, or the structures of the brow pad 102 and the jaw pad 104 that allow for interconnection.

The lower and intermediate portions of the jaw pad 104 overlie the ramus portion 56a of the wearer's jaw 56, wherein the lower portion 105 has a forwardly extending segment 105a that overlies a significant extent of the body portion 56b of the wearer's jaw 56. When the helmet 10 is worn, the jaw pads 104a, b expose, and do not overlie, the mental protuberance or chin 56c of the wearer's jaw 56. The lower jaw pad portion 105 has a substantially linear lower edge 105b, substantially linear front edge 105c extending upward from the lower edge 105b, and an upper edge 105d that is inclined from the front edge 105c. The front edge 105c and the lower edge 105b are set back from the frontal jaw flap edge 11a of the shell 11, thereby exposing an inner surface of the shell 11 in that region. The lower jaw pad portion 105 also has a curvilinear rear edge 105e that defines a recess 105f. In addition to the recess 105f, an upper portion of the rear jaw pad 105g has a series of angled edges, including a rear projection 105h that is positioned slightly above a midpoint of the overall height of the jaw pad 104 and that is aligned with the shell ear opening 11d, including an upper edge of the ear opening 11d. The rear projection 105h is slightly rearward of a lowermost projection 105i located between the lower edge 105b and the recess 105f.

As shown in FIGS. 2-15, the brow pad 102 and the jaw pad 104 have means for interconnecting to facilitate mating at the interconnection point 109. This mating at the interconnection point 109 provides continuous, interacting padding engagement between both of the wearer's jaw 56 and across the forehead 54, thereby preventing an appreciable interruption or discontinuity between the brow pad 102 and the jaw pads 104. In one embodiment, the interconnection means includes the brow pad 102 with peripheral connection portions 106 that are cooperatively dimensioned and positioned to interlock with connection portions 108 of the jaw pads 104a, b. Unlike conventional helmet padding assemblies that include pad elements that are adjacent or adjoining, the brow pad 102 and the jaw pad 104 feature specific structures that enables the interconnection discussed below. Preferably, the brow pad connection portion 106 is located along a lower, peripheral portion of the brow pad 102, and the jaw pad connection portion 108 is located along an upper portion of the jaw pad 104. Referring to FIGS. 2, 4 and 7, the brow pad's connection portion 106 includes a first connection segment 106a that extends substantially rearward and upward from a lower edge 107 of the brow pad 102. A second segment 106b extends substantially forward and upward from the first segment 106a of the connection portion 106. A third segment 106c extends substantially rearward and upward from the second segment 106b of the connection portion. The first, second and third segments 106a-c define an arrangement of projections and at least one recess 106d on each periphery of the brow pad 102 (see FIG. 7). The rear edge 102a of the brow pad 102 extends between the opposed connections portion 106, and defines a plurality of teeth 102b (see FIGS. 2 and 6) that intermesh with the leading edge portion of the crown pad 110. Referring to FIGS. 2, 4 and 9, the connection portion 108 of the jaw pad 104 includes a first connection segment 108a that extends substantially rearward and upward from a point on the jaw pad 104b that is substantially proximate the bottom edge 107 of the brow pad 102. A second segment 108b extends substantially forward and upward from the first segment 108a of the connection portion 108. A third segment 108c extends substantially rearward and upward from the second segment 108b of the connection portion 108. The first, second and third segments 108a-c define at least one front projection 108d (see FIG. 9) that is received by the recess 106d of the brow pad connection portion 106 in the assembled position of FIG. 2.

In an assembled position of FIGS. 2 and 3, the connection portions 106, 108 intermesh at the interconnection point 109 to facilitate engagement between the brow pad 102 and the jaw pad 104. Further, the first segment 106a of the brow pad 102 is disposed proximate and abuts the first segment 108a of the jaw pad 104b. In the assembled position, the lowermost point of the connection segment 108a is preferably adjacent the brow pad lower edge 107 and above the wearer's eye 58. The second segment 106b of the brow pad 102 is disposed proximate and abuts the second segment 108b of the jaw pad 104b. Likewise, the third segment 106c of the brow pad 102 is disposed proximate and abuts the third segment 108c of the jaw pad 104b. The interaction of the connection portion 106 of the brow pad 102 and the connection portion 108 of the jaw pads 104a, 104b limit movement there between and thereby maintain positioning between the brow pad 102 and the jaw pads 104a, 104b for the face frame assembly 101, as well as the face frame assembly 101 relative to the wearer 50.

As shown in FIGS. 8 and 11, the brow pad 102 and the jaw pads 104 are each made from a single type of padding material. Preferably, each of the brow pad 102 and the jaw pads 104 are molded as a single, unitary pad. Thus, the brow pad 102 is molded to form a single piece, and the jaw pad 104 is molded to form a single piece. In one embodiment the brow pad 102 and the jaw pads 104 are injection molded. In another embodiment, the jaw pad 104 is formed from at least two portions that are molded and positioned adjacent each other, thereby precluding an appreciable interruption or discontinuity between the portions. In this embodiment, the jaw pad 104 has a substantially uniform thickness at the region where the portions are adjacently positioned and over the length of the jaw pad 104. In the event the jaw pad 104 comprises multiple injection molded portions, the resulting jaw pad 104 mates with the brow pad 102 at the interconnection point 109, as described above. An example of the material used to form the brow pad 102 is DER-TEX SHOXS IV and having a 25% compression deflection (ASTM D-1056 standard) of 8-15 PSI (pounds per square inch) from DER-TEX Corp. of Saco, Me. The brow pad 102 has a substantially uniform thickness T₁ of from about 1 inch to about 1.25 inches, as shown in FIG. 8. The thickness of the brow pad 102 exceeds the thickness of the helmet shell 11, as shown in FIGS. 2A and 2B. Similarly, the jaw pads 104 may also be made from DER-TEX SHOXS IV from DER-TEX Corp. of Saco, Me. The jaw pads 104 have a thickness T₂ of from about 1 inch to about 1.25 inches, as shown in FIG. 11.

Referring to FIGS. 3 and 7, the brow pad 102 has a plurality of vent openings 118a, 118b. In the installed position of FIG. 2, each brow pad opening 118a, 118b is aligned with an opening in the helmet shell 11. The alignment of the vent openings 118a, 118b with the helmet shell openings allows warm air to vent or escape from the helmet 10, to increase the comfort of the wearer 50. Referring to FIG. 7, a pair of internal channels 119a extend from an intermediate portion of the lower edge 107 to the rear edge 102a, and a pair of peripheral channels 119b extend from a peripheral portion of the lower edge 107 to the peripheral edge of the brow pad 102, preferably proximate the notch 106d. Preferably, the brow pad 102 has a curvilinear configuration, and the channels 119a, b facilitate flexing of the brow pad 102.

As shown in FIGS. 12-15, the jaw pad 104 is removably positioned within a liner assembly 120. Preferably, the liner assembly 120 is treated with an anti-bacterial and/or anti-fungal application and is washable. The liner assembly 120 comprises at least one cushioning pad 122, preferably a plurality of cushioning pads 122a-122d (FIGS. 12 and 13). The cushioning pad 122 generally comprises a material that engages the wearer 50 and is softer than the material used to form the jaw pad 104b. The cushioning pad 122 may therefore be referred to as a comfort padding, while the jaw pad 104b may be referred to as an energy attenuating padding. The liner assembly 120 also comprises a backing material 124, opposite the cushioning pad 122 that engages the inner surface of the helmet shell 11. The backing material 124 may be connected to the cushioning pad 122 by a mesh fabric 126 that engages side portions of the jaw pad 104. The liner assembly 120 includes means for inflation 127 to offer a more customized fit and to account for anatomical differences among wearers 50. Inflation means 127 includes an inflation valve and stem assembly 128 that is in fluid communication with an inflatable chamber 130 positioned between the backing material 124 and the jaw pad 104. The inflatable chamber 130 is adapted to receive a fluid, typically air, supplied through a channel 129 by the inflation valve 128, which extends through an opening in the helmet shell 11. As the inflatable chamber 130 expands, the jaw pad 104 is displaced inward from the helmet shell 11 and towards the wearer 50 of the helmet 10. Thus, a more secure and customized fit may be achieved by the use of the inflation means 130. A conventional hand held pump having an inflation needle may be inserted into the inflation valve 128 to provide the desired amount of fluid, or air, into the chamber 130.

Turning to FIGS. 16A-20, the crown pad assembly 110, the side pad assembly 112, and the occipital cradle pad assembly 114 are shown removed from the helmet 10. The crown pad assembly 110 comprises a plurality of discrete energy attenuation elements or pad elements 132 that have a hexagonal configuration. The pad elements 132 are spaced apart, but interconnected by intervening connection segment 146. Because the pad elements 132 are discontinuous from each other, the pad elements 132 behave independently during use of the helmet 10—the response of a first pad element 132 to an impact force applied to the helmet 10 does not influence the response of a second pad element 132 to the impact force. Due to their hexagonal configuration and relative positioning, the leading portions of adjacent pad elements 132 of the crown pad assembly 110 define a group of crown recesses 111 (see FIG. 16A-16C) that are configured to engage with the teeth 102b (see FIG. 6) of the rear portion of the brow pad 102. Accordingly, the brow pad 102 has three portions—the rear portion and both side portions—that engage with other pads of the internal padding system 100. The rear portion of the brow pad 102 engages the crown pad assembly 110, while the side portions engage the jaw pads 104a, 104b.

The crown pad assembly 110 further comprises means for inflation including an inflation valve 134 to customize the fit of the crown pad assembly 110. The inflation valve 134 is adapted to provide an inflation fluid, such as air, to a portion of the hexagonally shaped pad elements 132. Referring to FIGS. 17 and 18, the hexagonal pad element 132 comprises a first housing portion 138 and a second housing portion 140 that are joined to form a housing enclosure 139 that encases a pad member 141. The pad member 141 comprises a first pad member portion 141a with energy (or force) attenuating pad material 142 that resides within the first housing portion 138 and a second pad member portion 141b with energy (or force) attenuating pad material 144 that resides within the second housing portion 140. FIG. 18 shows that the first and second pad member portions 141a, 141b have substantially the same configuration, including outer perimeter configuration, as the housing portions 138, 140 of the housing enclosure 139 that encase and contain the first and second pad member portions 141a, 141b, respectively. The energy attenuating pad material 142 is preferably a PVC nitrile foam or polyurethane foam, such as DerTex VN 600 PVC nitrile foam, having a density of at least approximately 5 pounds per cubic foot (PCF) and at least approximately a 25% compression deflection (ASTM D-1056 standard) of 8 pounds per square inch (PSI). In another embodiment, the pad material 142 is a “comfort pad material,” which is substantially different than energy attenuating pad material and is described in U.S. Pat. No. 3,882,547. A separation layer 143 is positioned between the two pad materials 142, 144 and extends between opposed seams 145 formed from joining side walls of the housing portions 138, 140. In one embodiment, the separation layer 143 has a thickness of 0.01 inch. The separation layer 143 is formed from an airtight material, such as vinyl, that partitions or separates the pad element 132 into a first chamber (or section) 132a including the housing portion 138 and the pad material 142, and a second chamber (or section) 132b including the housing portion 140 and the pad material 144. Thus, the pad element 132 is internally partitioned to include an inflatable second chamber 132b and an un-inflatable first chamber 132a. Although only the crown pad assembly 110 is shown as having a partitioned pad element 132 resulting from the separation layer 145, it is understood that the separation layer and partitioning could be employed with the elements of the side pad assembly 112 and the occipital cradle pad assembly 114.

As demonstrated by the different hatching lines in FIG. 18, the first and second housing portions 138, 140 are fabricated from different materials having dissimilar material properties, thereby combining to affect how the pad element 132 responds when an impact is applied to the helmet shell 11 and transmitted to the crown pad assembly 110. In one preferred embodiment, the first housing portion 138 is vacuum formed from a first type of vinyl, while the second housing portion 140 is vacuum formed from second type of vinyl. A vacuum forming process can be employed to fabricate the first and second housing portions 138, 140 from sheet stock to create a well that accommodates the pads 142, 144, respectively. From there, the first and second housings 138, 140 are sealed to form a seam 145 of the hexagonal pad element 132, wherein the separation layer 143 extends between opposed seams 145. The first and second housings 138, 140 are joined through heat sealing process such as high frequency welding, such as radio frequency welding. As shown in FIG. 18, the first housing 138 has a sidewall height H1 that exceeds a sidewall height H2 of the second housing 140. This means that the seam 145 and the separation layer 143 are offset from a midpoint of the overall sidewall height of the pad element 132. In one embodiment, the first sidewall height H1 is 0.75 inch and the second sidewall height H2 is 0.5 inch. Because of these different sidewall heights H1, H2, the first chamber 132a has a greater volume than the second chamber 132b in an un-inflated state. As mentioned above, the connection segment 146 resides between hexagonal pad elements 132. The connection segment 146 includes an upper portion formed from the same sheet stock material as the first housing 138 and a lower portion formed from the same stock sheet material as the second housing 140. The connection segment 146 also includes a channel 147 extending between adjacent pad elements 132.

Referring to FIGS. 16B-C, the crown pad assembly 110 includes multiple energy attenuation elements 132 that comprise: (i) a first pad element 132a with a first energy attenuation member 175 having an arrangement of six sides, which includes a first side 184 and a second side 185, (ii) a second pad element 132b with a second energy attenuation member 176 having an arrangement of six sides, which includes a first side 186 and a second side 187, and (iii) a third pad element 132c with a third energy attenuation member 177 having an arrangement of six sides, which includes a first side 188 and a second side 189. The first and second sides 184-189 of the first, second, and third energy attenuation members 177, 178, 179 are substantially planar and have approximately the same length, as shown in FIGS. 16B-16C, 17, and 18. Based on this configuration, the first and second sides 184-189 have edge segments 184a-189a that are: (a) substantially linear, (b) substantially the same length, and (c) are positioned adjacent or abut an extent of a crown pad assembly gap 179. This configuration also places: (i) the first edge segment 184a of the first energy attenuation member 175 substantially parallel with the second edge segment 187a of the second energy attenuation member 176, (ii) the first edge segment 188a of the third energy attenuation member 177 substantially parallel with the first edge segment 186a of the second energy attenuation member 186 and (iii) the second edge segment 189a of the third energy attenuation member 177 substantially parallel with the second edge segment 185a of the first energy attenuation member 175.

Again referring to FIGS. 16A-16C, the crown assembly gap 179 separates the first, second and third energy attenuation members 175, 176, 177 of the crown pad assembly 110 from each other. In particular, the crown assembly gap 179 comprises: (i) a first crown gap 180 formed between the first side 184 of the first energy attenuation member 175 and the second side 187 of the second energy attenuation member 176, (ii) a second crown gap 181 formed between the first side 186 of the second energy attenuation member 176 and the first side 188 of the third energy attenuation member 177, and (iii) a third crown gap 182 formed between second side 189 of the third energy attenuation member 177 and the second side 185 of the first energy attenuation member 175. Based on this configuration: (a) the first crown gap 180 is also formed between the first edge segment 184a of the first energy attenuation member 175 and the second edge segment 187a of the second energy attenuation member 176, (b) the second crown gap 181 is also formed between the first edge segment 186a of the second energy attenuation member 176 and the first edge segment 188a of the third energy attenuation member 177, and (c) the third crown gap 182 is also formed between second edge segment 189a of the third energy attenuation member 177 and the second edge segment 185a of the first energy attenuation member 175.

To adjust the fit of the crown pad 110, inflation fluid from the valve 134 can be supplied through the channel 147 to the second chamber 132b of the various pad elements 132, As denoted by the dotted lines, the lower portion of FIG. 18 shows the second chamber 132b in an inflated state, wherein inflation fluid has been supplied through the channel 147 to the second chamber 132b that is adjacent the inner surface 17 of the shell 11 when the crown pad 11 is installed within the helmet 10. When sufficiently inflated, the housing 140a of the second chamber 132b assumes a curvilinear configuration that substantially conforms to the curvilinear configuration of the inner shell surface 17 (see FIG. 18). Because the separation layer 143 is airtight, the first chamber 132a does not inflate and its housing 138 is not altered (e.g., curved or domed due to inflation) and remains generally linear, whereby a greater amount of the pad material 144 in the first chamber 132a remains in contact with the wearer's head 51. These attributes of the pad elements 132 improve both the fit of the crown pad 110 and the padding assembly 100 relative to the wearer's head 51, and the stability of the helmet 10 on the wearer's head 51, including when impact forces are applied to the helmet shell 11 and/or the faceguard 12. The channel 147 in the pad element connection section 146 allows inflation fluid to pass between various pad elements 132 for inflation or deflation of the second chamber 132b.

FIGS. 16A, 16D-16E, 19 and 20 show the side pad assembly 112 of the internal pad assembly 100, which also includes a plurality of discrete hexagonal pad elements 133. The side pad assembly 112 also includes an inflation valve 134 to supply inflation fluid through a channel 134a to the hexagonally shaped pad elements 133. The pad elements 132 are spaced apart but are interconnected by an intervening connection segment 154. The pad element 133 comprises a first housing portion 148 and a second housing portion 150 that are joined from a housing 149 that encase a pad member 152. As shown in FIG. 20, the pad member 152 of the side pad assembly 112 has substantially the same configuration, including outer perimeter configuration as the housing portions 148, 150 and thus the housing 149 that encases and contains the pad member 152. Although the pad member 152 is shown as being formed from a single type of material, the pad member 152 could be formed from two material types (as explained above). Thus, the pad member 152 could include energy attenuating pad material, comfort pad material, or a combination of both. Referring to the different hatching lines in FIG. 20, the first and second housing portions 148, 150 are fabricated from different materials having dissimilar material properties, thereby altering how the pad element 133 responds when an impact is applied to the helmet shell 11 and transmitted to the side pad assembly 112. In one embodiment, the first housing portion 138 is fabricated from a first type of vinyl, while the second housing portion 140 is fabricated from a second type of vinyl. As explained above, a vacuum forming process can be employed to seal the first and second housings 148, 150 at a seam 155. As shown in FIG. 20, the first housing 148 has a sidewall height H1 that is substantially the same as a sidewall height H2 of the second housing 150. Therefore, the seam 155 is located at a midpoint of the overall sidewall height of the pad element 133. The connection segment 154 also includes a channel 157 extending between adjacent pad elements 133. To adjust the fit of the side pad 112, inflation fluid from the valve 134 can be supplied through the channel 157 to the various pad elements 133. The lower portion of FIG. 20 shows a second housing 150a in an inflated position, wherein inflation fluid has been supplied through the channel 157 to the pad element 152 that is adjacent the wearer 50. The inflation of the pad element 133 provides a more precise fit of the side pad assembly 112 on the wearer 50 while accommodating the wearer's anatomical differences. Referring to FIGS. 2B, 9 and 16A, a first leading pad element 133b and a second leading pad element 133c define a cavity 137 (see FIG. 16A) configured to receive a rear projection 108e formed from a first rear segment 108f and a second rear segment 108g of the connection portion 108 of the jaw pad 104. As shown in the assembled position of FIG. 2B, the rear projection 108e is received by the cavity 137 wherein the first rear segment 108f is positioned adjacent the first leading pad element 133b and the second rear segment 108g is positioned adjacent the second leading pad element 133c. Accordingly, the connection portion 108 is positioned between the crown pad 110 and the brow pad 102, and provides for mating of the jaw pad 104 with both the crown pad 110 and the brow pad 102.

Referring to FIGS. 16A, 16D-E, the side pad assembly 112 includes multiple pad elements 133 that comprise: (i) a first pad element 233a with a first energy attenuation member 275 having an arrangement of six sides, which includes a first side 284 and a second side 285, (ii) a second pad element 233b with a second energy attenuation member 276 having an arrangement of six sides, which includes a first side 286 and a second side 287, and (iii) a third pad element 233c with a third energy attenuation member 277 having an arrangement of six sides, which includes a first side 288 and a second side 289. The first and second sides 284-289 of the first, second and third energy attenuation members 277, 278, 279 are substantially planar and have approximately the same length, as shown in FIGS. 16D-16E, 19, and 20. Based on the configuration, the first and second sides 284-289 have edge segments 284a-289a that are: (i) substantially linear, (ii) substantially the same length, and (iii) are positioned adjacent or abut an extent of a side pad assembly gap 301. This configuration also places: (i) the first edge segment 284a of the first energy attenuation member 275 substantially parallel with the second edge segment 287a of the second energy attenuation member 276, (ii) the first edge segment 288a of the third energy attenuation member 277 substantially parallel with the first edge segment 286a of the second energy attenuation member 286 and (iii) the second edge segment 289a of the third energy attenuation member 277 is substantially parallel with the second edge segment 285a of the first energy attenuation member 275.

Again referring to FIGS. 16A, 16D-E, the side pad assembly gap 310 separates the first, second, and third energy attenuation members 275, 276, 277 of the side pad assembly 112 from each other. In particular, the side assembly gap 301 is comprised of: (i) a first side gap 280 formed between the first side 284 of the first energy attenuation member 275 and the second side 287 of the second energy attenuation member 276, (ii) a second side gap 281 formed between the first side 286 of the second energy attenuation member 276 and the first side 288 of the third energy attenuation member 277, and (iii) a third side gap 282 formed between second side 289 of the third energy attenuation member 277 and the second side 285 of the first energy attenuation member 275. Based on this configuration: (i) the first side gap 280 is also formed between the first edge segment 284a of the first energy attenuation member 275 and the second edge segment 287a of the second energy attenuation member 276, (ii) the second side gap 281 is also formed between the first edge segment 286a of the first energy attenuation member 276 and the first edge segment 288a of the third energy attenuation member 277, and (iii) the third gap 282 is also formed between second edge segment 289a of the third energy attenuation member 277 and the second edge segment 285a of the first energy attenuation member 275.

FIGS. 16A, 16D-16E, and 21-23 depict the inflatable occipital cradle pad assembly 114 which, as explained below, fills the space or void V (see FIGS. 22 and 23) below the wearer's occipital protuberance 57 of the occipital bone to cradle and stabilize the helmet 10 on the wearer's head 51. When installed within the shell 11, the occipital pad assembly 114 extends along the rear lower edge 11b of the shell 11, wherein no other pad element resides between the occipital pad assembly 114 and the rear lower edge 11b. The occipital pad assembly 114 structurally and functionally interacts with the side pad assembly 112 to increase helmet 10 stability during playing of the contact sport, including when the helmet 10 receives an impact or a series of impacts, both of which are common during the play of football, lacrosse and hockey. The occipital pad assembly 114 comprises an arrangement of pad elements that are specifically designed to engage the lower extent of the occipital protuberance 57 of wearer's head 51. The occipital cradle pad assembly 114 comprises a first peripheral pad element 156a, a second peripheral pad element 156b, a central pad element 157, a first intermediate pad element 158a and a second intermediate pad element 158b. In the embodiment shown, the first and second peripheral pad elements 156a, b have a hexagonal configuration that includes a first edge segment 185a, b that has a length substantially equal to the length of the first edge segments 184a, 186a, 188a, 284a, 286a, 288a of the first through the third energy attenuation members 175-177 and 275-277 of the crown pad assembly 110 and the side pad assembly 112, respectively. Additionally, the central pad element 157 has a trapezoidal configuration, and the first and second intermediate pad elements 158a, b have a pentagonal configuration. The first and second intermediate pad elements 158a, b reside adjacent or below the central pad element 157 and are separated by a central gap 158c that extends from a lower edge of the intermediate pad elements 158 to the central pad element 157. The first and second peripheral pad elements 156a, b extend outward or peripherally from a main portion of the pad assembly 114 by a connection segment 159. The first and second peripheral pad elements 156a, b extend transversely upward past the intermediate pad element 158a, b and slightly beyond the central pad element 157. A peripheral slot 156c extends transversely between the peripheral pad segment 156a, b and the intermediate pad element 158a, b, and from the lower edge to the connection segment 159. In the embodiment of FIG. 21, the peripheral slot 156c has an initial slot segment leading to an interior slot segment, wherein the width of the latter exceeds the width of the former. The gap 158c and the peripheral slots 156c facilitate flexing of the occipital cradle pad assembly 114 during installation within the helmet shell 11 and proper positioning of the pad assembly 114 relative to the helmet shell 11.

The occipital cradle pad assembly 114 also comprises an inflation valve 134 residing in an elevated portion 135 of the assembly 114. The inflation valve 134 is adapted to provide an inflation fluid, such as air, to the pad elements 156, 158. An air channel 134a extends from the valve 134 to the pad elements 156, 158. The occipital cradle pad assembly 114 is removably secured to the inner surface 17 of the helmet shell 11 by a connector, such as Velcro® connector 136. The occipital cradle pad assembly 114 is symmetric about an axis extending through the inflation valve 134 whereby the assembly 114 has first (right) and second (left) portions. A portion of the elevated portion 135, the first peripheral element 156a, the central pad element 157 and the first intermediate element 158a define a first well 160a. Similarly, the elevated portion 135, the second peripheral element 156b and the second intermediate element 158ba define a second well 160b. The combination of the elevated portion 135, the wells 160a, b and the upper portion of the peripheral pad elements 156a, b provide a series of projections and recesses that facilitate engagement of the occipital pad assembly 114 with a lower portion (or trailing edge portion) of the side pad assembly 112. As shown in FIG. 16, the lower portion of the side pad assembly 112 has a central recess 112a that receives the central elevated portion 135, and a pair of intermediate recesses 112b, c wherein each recess 112b, c receives an upper extent of the peripheral pad element 156a,b. When the occipital cradle pad assembly 114 and the side pad assembly 112 are installed in the helmet 10, the central elevated portion 135 is positioned between the helmet shell 11 and the pad element 133a of the side pad assembly 112 adjacent (see FIG. 16A).

The occipital cradle pad assembly 114 includes a housing 164 for the pad elements 156-158 consisting of a first vinyl sheet 166 vacuum formed with a second vinyl sheet 168. Referring to FIGS. 22 and 23, a portion of the housing 164 that is in fluid communication with the valve 134 and air channel 134a is inflatable to allow for independent and customized engagement of the intermediate pad element 158a with the occipital protuberance 57. As shown, the central pad element 157 and the intermediate pad element 158 include at least one pad member 170, such as Dertex VN 600 PVC nitrile foam padding. In one embodiment, the central pad element 157 and the intermediate pad element 158 have a thickness ranging from 0.5 to 1.0 inch. Referring back to FIG. 21, the housing 164 includes peripheral sealed regions 172 adjacent the slot 156c and the intermediate pad element 158. The lower extent of the sealed regions 172a, b, the intermediate pads 158a, b and the peripheral pads 156a, b combine to define a lower edge of the occipital pad assembly 114 that is substantially adjacent the lower rear edge 11b of the helmet shell 11. As shown in FIGS. 22 and 23, the lower rear edge 11b is received by a rear nameplate or bumper 174, wherein the occipital pad assembly 114 engages the rear bumper 174.

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.

Claims

1. A protective sports helmet comprising: a helmet shell including a crown region; anda crown energy attenuation assembly positioned within the crown region of the helmet shell, the crown energy attenuation assembly including: a first energy attenuation member having a hexagonal configuration;a second energy attenuation member having a hexagonal configuration;a third energy attenuation member having a hexagonal configuration;a first crown gap formed between an extent of the first energy attenuation member and the second energy attenuation member,a second crown gap formed between an extent of the second energy attenuation member and the third energy attenuation member, anda third crown gap formed between an extent of the third energy attenuation member and the first energy attenuation member; andenergy attenuating material positioned (i) external to the first, second, and third energy attenuation members and (ii) internal to the helmet shell.

2. The protective sports helmet of claim 1, wherein the first energy attenuation member includes a first edge segment adjacent the first crown gap and a second edge segment adjacent the third crown gap; wherein the second energy attenuation member includes a first edge segment adjacent the second crown gap and a second edge segment adjacent the first crown gap; andwherein the first edge segment of the first energy attenuation member is substantially parallel with the second edge segment of the second energy attenuation member.

3. The protective sports helmet of claim 2, wherein the third energy attenuation member includes a first edge segment adjacent the second crown gap and a second edge segment adjacent the third crown gap; and wherein (i) the first edge segment of the third energy attenuation member is substantially parallel with the first edge segment of the second energy attenuation member and (ii) the second edge segment of the third energy attenuation member is substantially parallel with the second edge segment of the first energy attenuation member.

4. The protective sports helmet of claim 1, wherein the crown energy attenuation assembly further comprises a layer positioned (i) external to a portion of the first, second, and third energy attenuation members and (ii) internal to the energy attenuation material, and wherein said energy attenuation material is positioned between the layer and the helmet shell.

5. The protective sports helmet of claim 1, wherein the first energy attenuation member includes a comfort padding material that includes foam.

6. The protective sports helmet of claim 1, wherein the first, second, and third crown gaps are radially arranged approximately 120 degrees apart from one another.

7. The protective sports helmet of claim 1, further including: a side energy attenuation assembly positioned within a side region of the helmet shell, the side energy attenuation assembly including: a first side energy attenuation member having a hexagonal configuration;a second side energy attenuation member having a hexagonal configuration;a third side energy attenuation member having a hexagonal configuration; andenergy attenuating material positioned (i) external to the first, second, and third side energy attenuation members and (ii) internal to the helmet shell.

8. The protective sports helmet of claim 1, wherein the first energy attenuation member is positioned within a first housing, the second energy attention member is positioned within a second housing, the third energy attenuation member is positioned within a third housing.

9. A protective sports helmet comprising: a helmet shell; andan energy attenuation assembly positioned within the helmet shell and including: a first energy attenuation member having an arrangement of edge segments including a first substantially linear edge segment and a second substantially linear edge segment;a second energy attenuation member having an arrangement of edge segments including a first substantially linear edge segment and a second substantially linear edge segment;a third energy attenuation member having an arrangement of edge segments including a first substantially linear edge segment and a second substantially linear edge segment;a first gap is positioned between the first substantially linear edge segment of the first energy attenuation member and the second substantially linear edge segment of the second energy attenuation member;a second gap is positioned between the first substantially linear edge segment of the second energy attenuation member and the first substantially linear edge segment of the third energy attenuation member;a third gap is positioned between the second substantially linear edge segment of the third energy attenuation member and the second substantially linear edge segment of the first energy attenuation member;wherein the first substantially linear edge segment of the third energy attenuation member is substantially parallel with the first substantially linear edge segment of the second energy attenuation member; andwherein the first substantially linear edge segment of the first energy attenuation member is substantially parallel with the second substantially linear edge segment of the second energy attenuation member.

10. The protective sports helmet of claim 9, wherein the first, second, and third energy attenuation members have a hexagonal configuration.

11. The protective sports helmet of claim 9, wherein an extent of one of the first, second, and third energy attenuation members is removably coupled within the helmet shell using a hook and loop fastener assembly.

12. The protective sports helmet of claim 9, further comprising a layer and an energy attenuating material, and wherein the layer is positioned between the first energy attenuation member and the energy attenuating material.

13. The protective sports helmet of claim 9, wherein the first, second, and third gaps are radially arranged approximately 120 degrees apart from one another.

14. The protective sports helmet of claim 9, wherein the second substantially linear edge segment of the third energy attenuation member is substantially parallel with the second substantially linear edge segment of the first energy attenuation member.

15. A protective sports helmet comprising: a helmet shell including a crown region, a side region, and a rear region; anda crown energy attenuation assembly positioned within the crown region of the helmet shell, the crown energy attenuation assembly including: a first energy attenuation element including a foam padding material positioned within a first housing, the first housing having a first edge and being positioned adjacent a first gap with a first gap area;a second energy attenuation element including a foam padding material positioned within a second housing, the second housing having a first edge and being positioned adjacent a second gap with a second gap area;a third energy attenuation element including a foam padding material positioned within a third housing, the third housing having both a first edge positioned adjacent the second gap and a second edge positioned adjacent a third gap having a third gap area;wherein the first, second, and third gaps are radially arranged approximately 120 degrees apart from one another; andenergy attenuating material positioned between at least the first energy attenuation element and the helmet shell.

16. The protective sports helmet of claim 15, wherein the crown energy attenuation assembly is removably coupled in the crown region of the helmet shell using a hook and loop fastener assembly.

17. The protective sports helmet of claim 15, wherein the first edge of the second energy attenuation element is substantially parallel with the first edge of the third energy attenuation element.

18. The protective sports helmet of claim 15, further comprising an energy attenuating material positioned between the first energy attenuation member element and the helmet shell.

19. The protective sports helmet of claim 15, wherein the energy attenuating material and the foam padding material have different material properties than one another.