US20220061448A1 - Protective sports helmet - Google Patents
Protective sports helmet Download PDFInfo
- Publication number
- US20220061448A1 US20220061448A1 US17/523,689 US202117523689A US2022061448A1 US 20220061448 A1 US20220061448 A1 US 20220061448A1 US 202117523689 A US202117523689 A US 202117523689A US 2022061448 A1 US2022061448 A1 US 2022061448A1
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- US
- United States
- Prior art keywords
- shell
- faceguard
- segment
- helmet
- region
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Abandoned
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Classifications
-
- A—HUMAN NECESSITIES
- A42—HEADWEAR
- A42B—HATS; HEAD COVERINGS
- A42B3/00—Helmets; Helmet covers ; Other protective head coverings
- A42B3/04—Parts, details or accessories of helmets
- A42B3/18—Face protection devices
- A42B3/20—Face guards, e.g. for ice hockey
-
- A—HUMAN NECESSITIES
- A42—HEADWEAR
- A42B—HATS; HEAD COVERINGS
- A42B3/00—Helmets; Helmet covers ; Other protective head coverings
- A42B3/04—Parts, details or accessories of helmets
- A42B3/0406—Accessories for helmets
-
- A—HUMAN NECESSITIES
- A42—HEADWEAR
- A42B—HATS; HEAD COVERINGS
- A42B3/00—Helmets; Helmet covers ; Other protective head coverings
- A42B3/04—Parts, details or accessories of helmets
- A42B3/08—Chin straps or similar retention devices
-
- A—HUMAN NECESSITIES
- A42—HEADWEAR
- A42B—HATS; HEAD COVERINGS
- A42B3/00—Helmets; Helmet covers ; Other protective head coverings
- A42B3/04—Parts, details or accessories of helmets
- A42B3/28—Ventilating arrangements
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B71/00—Games or sports accessories not covered in groups A63B1/00 - A63B69/00
- A63B71/08—Body-protectors for players or sportsmen, i.e. body-protecting accessories affording protection of body parts against blows or collisions
- A63B71/081—Body-protectors for players or sportsmen, i.e. body-protecting accessories affording protection of body parts against blows or collisions fluid-filled, e.g. air-filled
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B71/00—Games or sports accessories not covered in groups A63B1/00 - A63B69/00
- A63B71/08—Body-protectors for players or sportsmen, i.e. body-protecting accessories affording protection of body parts against blows or collisions
- A63B71/10—Body-protectors for players or sportsmen, i.e. body-protecting accessories affording protection of body parts against blows or collisions for the head
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2102/00—Application of clubs, bats, rackets or the like to the sporting activity ; particular sports involving the use of balls and clubs, bats, rackets, or the like
- A63B2102/14—Lacrosse
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2102/00—Application of clubs, bats, rackets or the like to the sporting activity ; particular sports involving the use of balls and clubs, bats, rackets, or the like
- A63B2102/22—Field hockey
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2102/00—Application of clubs, bats, rackets or the like to the sporting activity ; particular sports involving the use of balls and clubs, bats, rackets, or the like
- A63B2102/24—Ice hockey
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2209/00—Characteristics of used materials
- A63B2209/10—Characteristics of used materials with adhesive type surfaces, i.e. hook and loop-type fastener
-
- A—HUMAN NECESSITIES
- A63—SPORTS; GAMES; AMUSEMENTS
- A63B—APPARATUS FOR PHYSICAL TRAINING, GYMNASTICS, SWIMMING, CLIMBING, OR FENCING; BALL GAMES; TRAINING EQUIPMENT
- A63B2243/00—Specific ball sports not provided for in A63B2102/00 - A63B2102/38
- A63B2243/0066—Rugby; American football
- A63B2243/007—American football
Definitions
- 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 an energy attenuating faceguard mounting system that reduces impact forces received by a faceguard secured to the helmet.
- Helmets for contact sports 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 faceguard is rigidly secured to the shell by a plurality of connectors, whereby the faceguard can sustain a number of impacts during the course of play while remaining connected to the shell.
- Most faceguards include a plurality of intersecting and/or overlapping bars that form openings through which the wearer views the field of play. With conventional helmets, the upper faceguard bars directly contact the lower frontal portion of the helmet shell, which is referred to as the “brow region” of the shell.
- One existing faceguard connector is a plastic U-shaped strap member that has a receiver portion that encircles a bar of the faceguard.
- This strap connector includes a tab portion, wherein a threaded fastener, such as a screw, extends through the tab portion and into the shell to secure the connector and the faceguard to the helmet.
- a threaded fastener such as a screw
- these U-shaped strap connectors are found above the brow region of the shell and along each ear flap to join the faceguard to the shell.
- a second existing faceguard connector is disclosed in U.S. Pat. No. 6,934,971, which is owned by Riddell Inc., the assignee of the present application.
- That connector marketed under the Isolator System brand name, includes a nut, a bushing, a grommet, a rectangular bracket and a threaded fastener (screw).
- the bracket includes a first channel that receives a first bar of the faceguard and a second channel that receives a second bar, wherein the faceguard bars are positioned between the shell and the bracket.
- the fastener extends through the bracket and the shell and is received by the nut (residing within the shell) to couple the faceguard to the shell.
- the threaded fastener is employed to secure the connector to the shell and as a result, a rotational force is applied to tighten for securement and loosen the fastener to permit removal of the bracket and faceguard.
- a faceguard connector above the brow region of the shell is the transmission of faceguard impact forces. Because the faceguard is in direct contact with the shell, a significant extent of a faceguard impact force is transmitted from the faceguard to the shell. Depending upon its severity and magnitude, an extent of the impact force may be transmitted through the internal padding assembly to the wearer of the helmet.
- the present invention is directed to a protective sports helmet that includes a number of improvements intending to increase the protective nature of the helmet.
- the helmet features an energy attenuating faceguard mounting system, which includes at least one connector that secures the faceguard (or face mask) to the helmet shell without a connection point to the shell's brow region.
- the lack of a brow region connection point results in a gap or clearance between the faceguard and the shell that has a functional interplay with the connector upon an impact to the faceguard.
- 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 completely prevent head injuries to football players.
- FIG. 1 is a perspective view of an embodiment of a sports helmet having an energy attenuating system of the invention, the system including a faceguard and a dynamic faceguard connector assembly;
- FIG. 1A is a perspective view of the helmet of FIG. 1 , where the internal padding of the sport helmet has been removed;
- FIG. 1B is an elevated perspective view of the helmet of FIG. 1 ;
- FIG. 2 is a front view of the helmet of FIG. 1 , including an alternative faceguard design
- FIG. 2A is a front view of the helmet of FIG. 1 ;
- FIG. 3 is a side view of the helmet of FIG. 1 , including a wearer of the helmet being partially shown in phantom lines;
- FIG. 3A is a side view of a portion of the helmet of FIG. 1 showing the energy attenuating system of the helmet;
- FIG. 4A is a perspective view of the dynamic faceguard connector of the energy attenuating system of the helmet of FIG. 1 ;
- FIG. 4B is a side view of the dynamic faceguard connector of the energy attenuating system of the helmet of FIG. 1 ;
- FIG. 4C is a top view of the dynamic faceguard connector of the energy attenuating system of the helmet of FIG. 1
- FIG. 5A is a perspective view of a nameplate used with the helmet of FIG. 1 ;
- FIG. 5B is a cross-sectional view of the nameplate of FIG. 5 a , showing the nameplate mounted to the helmet and a gap G between the faceguard member and the helmet;
- FIG. 6 is a top view of the helmet of FIG. 1 , showing the energy attenuating system of the helmet in an installed position;
- FIG. 6A is a partial top view of the helmet of FIG. 1 showing the energy attenuating system of the helmet in the installed position;
- FIG. 7 is a partial top view of the helmet of FIG. 1 showing the energy attenuating system of the helmet wherein a generally on-center force F is applied to the faceguard;
- FIG. 8 is a partial top view of the helmet of FIG. 1 showing the energy attenuating system of the helmet wherein a generally off-center force F is applied to the faceguard;
- FIG. 9 is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet of FIG. 6A and shown within dotted lines therein;
- FIG. 9A is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet of FIG. 8 and shown within dotted lines therein;
- FIG. 10 is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet of FIGS. 7 and 8 and shown within dotted lines therein;
- FIG. 11 is a side view of the helmet of FIG. 1 showing a transitional region of the shell;
- FIG. 12 is a front view of the helmet shell of FIG. 1 ;
- FIG. 13 is a cross-sectional view of the shell portion of the helmet taken through line 13 - 13 of FIG. 12 ;
- FIG. 14 is a partial cross-sectional view of the shell portion of the helmet shown within dotted lines of FIG. 13 ;
- FIG. 15 is a partial sectional view of a transitional region of the shell portion of the helmet showing the curvature of a front portion of the shell and a rear portion of the shell;
- FIG. 16 is a partial sectional view of a transitional region of the shell portion of the helmet showing the curvature of the front portion of the shell, the rear portion of the shell, and a transitional portion of the shell;
- FIG. 17 is a rear view of the helmet of FIG. 1 .
- a football helmet 10 in accordance with the present invention is shown to generally include: an outer shell 11 with an ear flap 12 and a jaw flap 13 , an energy attenuating faceguard mounting system 14 comprising a faceguard 35 that spans a frontal shell opening 11 a and at least one dynamic faceguard connector 16 , and an internal padding assembly 300 .
- the outer shell 11 includes a frontal opening 11 a defined by an arrangement of edges including an interior frontal edge 11 b (see FIG. 3A ) and an upper frontal edge 11 d (see FIGS. 3, 3 a ), where the upper frontal edge 11 d of the frontal opening 11 a can also be considered a lower frontal edge of the shell 11 .
- the outer shell 11 also includes a brow region 11 c (see FIG. 1A ) that resides above the upper frontal edge 11 d and that overlies a brow of the wearer 500 of the helmet 10 , when the helmet 10 is worn (see FIG. 3 ).
- the outer shell 11 also includes a thickened segment 11 g that extends laterally along the upper frontal edge 11 d and into an interface area 11 e (see FIGS. 3, 5B, 12 and 13 ). As shown in FIGS. 5B and 13 , an angled transition wall 11 h leads to the thickened segment 11 g. Focusing on FIGS. 1B and 12 , the thickened segment 11 g and the interface area 11 c are raised relative to the adjacent portion of the shell 11 .
- the outer shell 11 is preferably made of a 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.
- the shell is made from a fiber reinforced plastic resin, wherein carbon fibers are utilized.
- Outer shell 11 has an inner wall surface 17 ( FIG. 12 ) and an outer wall surface 18 .
- the shell 11 further includes a crown 19 , a back or rear 20 , a front 21 , a lower edge surface 22 , and two side regions 24 (which include the ear flap 12 and jaw flap 13 ).
- shell 11 is adapted to receive the head 525 of a wearer 500 of the helmet 10 .
- the wearer or player 500 has a jaw or mandible 526 ( FIG. 3 ) that generally comprises a substantially vertical ramus portion 527 , a body or side portion 528 , and a frontal or mental protruberance or chin portion 529 .
- the body portion 528 extends between the ramus portion 527 and the chin 529 .
- the ramus portion 527 includes an upper segment with coronoid and condyloid processes that are proximate and forward of ears 530 of wearer 500 .
- each side region 24 of the shell 11 includes an ear flap 12 , which is adapted to generally overlie an ear 530 ( FIG. 3 ) and portion of a cheek of the wearer 500 .
- Each ear flap 12 generally extends downwardly from the side region 24 to the lower edge surface 22 of shell 11 .
- Each ear flap 12 includes a jaw flap 13 that extends from its corresponding ear flap 12 forwardly toward the front 21 of the shell 11 .
- the jaw flap 13 is adapted to generally extend to overlie a portion of the body portion 528 of the jaw 526 of the wearer 500 of the helmet 10 . As shown in FIG.
- jaw flap 13 extends forwardly to overlie a forwardly disposed portion of the jaw 526 disposed toward the chin 529 of wearer 500 .
- the jaw flap 13 extends forwardly enough to overlie a portion of the side of the chin 529 of wearer 500 , but not the entire chin 529 .
- the jaw flap 13 does not need to extend to completely cover the chin 529 of the wearer 500 , but it is contemplated that it may extend to completely cover the chin 529 in some embodiments, or based on the specific anatomy of some wearers. It is further contemplated that the jaw flap 13 will not cover any portion of the chin 529 of the wearer 500 in other embodiments, or based on the specific anatomy of some wearers.
- helmets 10 of the present invention are generally made with outer shells 11 of varying sizes, dependent upon the size of the head of the particular wearer of the helmet. It is also noted that players are fitted for helmets by trained personnel in accordance with written fitting guidelines.
- FIG. 3 a properly-sized helmet 10 is shown superimposed upon what is believed to be an average size head of a wearer of the helmet 10 , whereby jaw flap 13 is shown to generally overlie the entire ramus 527 of the jaw 526 and at least some of the body portion 528 of the jaw 526 , including a forwardly disposed portion of jaw 526 adjacent the chin 529 of wearer 500 , including overlying at least some portion of the side of the chin 529 of wearer 500 .
- FIG. 3 is not a representation of all sizes of heads and all types of chin structures, such as chins which may greatly extend outwardly away from the head of the wearer, it should be understood that it is perhaps possible that someone wearing a helmet 10 in accordance with the present invention may have a larger or smaller side portion of his or her chin extending outwardly further beyond the outer periphery of jaw flap 13 .
- jaw flap 13 will overlie some portion of the body 528 of the jaw 526 of virtually all wearers of helmets 10 .
- the helmet shell 11 has an arrangement of complex contours.
- the shell 11 has a raised central band 60 extending rearward from the front shell portion 21 and along the crown 19 .
- the raised central band 60 has an initial frontal width that is reduced as the band 60 extends rearward through the crown 19 .
- the initial frontal width is approximately 5 to 6 inches.
- the band 60 has an initial frontal height defined by a beveled (or inclined) sidewall 60 a that is reduced along the band 60 , whereby a rear segment of the band 60 is substantially flush with the outer surface 18 of the shell 11 , preferably being flush rearward of a midpoint of the crown 19 .
- a pair of opposed front raised lateral ridges 62 extend transversely and substantially upward from the band 60 and towards the ear flap 12 .
- the raised lateral ridge 62 has an initial frontal height defined by a first beveled sidewall segment 62 a that extends laterally and downwardly from the sidewalls 60 a of the band 60 .
- the raised lateral ridges 62 have a second beveled sidewall segment 62 b that extends laterally and upwardly from the first beveled sidewall segment 62 a and towards the ear flap 12 .
- a midpoint of the second sidewall segment 62 b is approximately 1.5 to 2 inches above the uppermost faceguard bar 52 a and the frontal opening upper edge 11 d.
- the second sidewall segment 62 b is reduced along the raised lateral ridge 62 , whereby a peripheral segment of the raised lateral ridge 62 is substantially flush with the outer shell surface 18 .
- the raised lateral ridge 62 is flush with the outer shell surface 18 at a point that is rearward of the dynamic connector 16 , substantially aligned with the upper chin strap connector 45 a, and/or substantially aligned with the angled frontal ridge 12 b of the ear opening 12 a. As shown in FIG.
- the rear openings 32 e are positioned in the rear 20 of the shell 11 and between a rear edge 22 and a raised lateral ridge chord 34 that extends: (i) between uppermost points 63 of the raised lateral ridges 62 , and (ii) around the rear 20 of the shell 11 .
- a first set of ventilation openings, or air vents, 32 a - c are arranged along the sidewall 60 a of the band 60 .
- the helmet 10 is symmetric and it is understood that the structures and features shown on the left half, including openings 32 a - c along the right sidewall of the band 60 , are also present on the right half (not shown) of the helmet 10 .
- the openings 32 a, 32 b, 32 c in the first set on the left half of the helmet 10 are collinear with each other, and the openings in the second set (on the right half of the helmet 10 ) are also collinear with each other.
- the band 60 has a rearward taper, the distance between opposed openings 32 a, 32 b, 32 c in the first and second sets, as measured across the band 60 , decreases.
- the initial frontal opening 32 a is adjacent to an inner shoulder of the raised lateral ridge 62 and the band 60 .
- the frontal vent opening 32 a is positioned substantially adjacent to the raised central band 60 and the raised lateral ridge 62 .
- the frontal vent opening 32 a is located adjacent to a base portion of the sidewall 60 a and the first sidewall segment 62 a, as these sidewalls 60 a, 62 a extend outward from the outer surface 19 of the shell 11 .
- the shell 11 further includes a raised rear band 64 that extends from the crown 19 rearward to the rear shell portion 20 .
- the raised rear band 64 has a width that remains substantially constant as the band 64 extends rearward and downward.
- the rear band 64 also has opposed beveled (or inclined) sidewalls 64 a that increases as the band 64 extends rearward.
- An initial segment of the band 64 commences forward of the rearmost opening 32 c and is substantially flush with the shell 11 .
- a pair of opposed rear beveled ridges 68 extend outward and downward from a rear segment of the band 64 .
- the rear beveled ridges 68 have sidewalls 68 a that decrease along their length whereby the ridges 68 gradually blend into the shell 11 .
- a ventilation opening 32 d resides adjacent an inner shoulder 68 b between the ridges 68 and the band 64 .
- the ventilation opening 32 d has a triangular configuration.
- the rear band 64 terminates proximate a substantially horizontal ledge 70 that extends between the side regions 24 of the helmet 10 .
- the substantially horizontal ledge 70 includes an angled surface 72 extending between the rear band 64 and the outer shell surface 18 .
- the rear shell portion 20 includes a pair of recessed regions 74 in an opposed positional relationship.
- the recessed region 74 is defined by an arrangement of angled walls 74 a that form a generally U-shaped configuration.
- a rear opening 32 e resides within the recessed region 74 and is positioned adjacent to a frontal or leading wall 74 b of the angled walls 74 a and between an upper transverse wall 74 c and a lower transverse wall 74 d.
- the rear opening 32 e has an elongated configuration with a major axis that is substantially vertical when the helmet 10 is positioned on the wearer's head. Further, the rear opening 32 e has an upper width that exceeds a lower width. As shown in FIGS.
- the rear openings 32 c are positioned in the rear 20 of the shell 11 and below a first chord 31 that extends: (i) between the forward-most points 29 of the ear openings 12 a and (ii) around the rear 20 of the shell 11 .
- the shell 11 is configured such that the distance between the sidewall 60 a of the raised central band 60 is less than the distance between the outer edges of the rear openings 32 e.
- the helmet 10 includes a chin protector 40 that engages the chin 529 of wearer 500 and couples with the shell 11 in order to secure the helmet 10 on the wearer's head.
- the chin protector 40 includes a central protective member 42 that engages the wearer's chin 529 and at least two flexible members or straps 43 , 44 extending from the central member 42 .
- the upper flexible member 43 engages with an upper connector 45 a extending outward from the shell 11 above an ear opening 12 a in the ear flap 12 and preferably rearward of the faceguard connector 16 .
- the lower flexible member 44 engages with a lower connector 45 b extending outward from the shell 11 below the ear opening 12 a.
- a frontal portion of the ear opening 12 a is defined by an angled frontal ridge 12 b with a beveled side wall 12 c (see FIG. 3A ).
- An upper recessed channel 46 extends rearward from an interior frontal edge 11 b of the shell frontal opening 11 a and along the upper periphery of the jaw flap 13 .
- the upper recessed channel 46 is adjacent an upper beveled surface 13 a of the jaw flap 13 (see FIG. 3A ), and the upper connector 45 a is aligned with the upper recessed channel 46 .
- a peripheral downwardly extending transverse bar 52 g is cooperatively dimensioned with the upper channel 46 such that an upper flexible member 43 of the chin protector 40 is positioned between the transverse bar 52 g and the upper channel 46 .
- a lower recessed channel 48 extends from the lower edge 22 of the shell 11 upward and rearward along the lower periphery of the jaw flap 13 .
- the lower recessed channel 48 is adjacent a lower beveled surface 13 b of the jaw flap 13 , and the lower connector 45 b is aligned with the lower recessed channel 48 .
- the jaw flap 13 defines an outermost jaw flap surface 13 c of the shell 11 in the side region of the helmet 10 .
- the shell 11 also includes a notch 47 formed in the lower edge shell surface 22 and below the ear opening 12 a, and preferably, the notch 47 is aligned with the lower channel 48 .
- notch 47 has at least one angled segment 47 a and potentially a plurality of angled segments 47 a, b that result in a generally V-shaped configuration; however, other shapes of notches, if desired, could be utilized.
- Each flexible member 43 , 44 includes a coupler 49 with a female snap connector that engages with the male upper and lower connectors 45 a, b , respectively, to define a secured position.
- the chin protector 40 When the chin protector 40 is in a secured position and the helmet 10 is on the wearer's head 500 (see FIG. 3 ), the upper channel 46 receives an extent 43 a of the upper flexible member 43 and the lower channel 48 receives an extent 44 a of the lower flexible member 44 .
- the upper and lower flexible members 43 , 44 are retained within the upper and lower channels 46 , 48 , respectively.
- a second extent 44 b of the lower flexible member 44 passes through notch 47 which improves stability of the lower flexible member 44 while minimizing undesired movement of the member 44 .
- the helmet tends to roll forwardly about a virtual pivot point located slightly above the ear openings.
- Notch 47 assists in resisting the undesired rolling effect by redirecting the lower flexible member's 44 line of action to a location farther away from the virtual pivot point.
- the securement configuration resulting from the channels 46 , 48 and the notch 47 provide an improvement over the conventional 4 point hookup, or a “high hookup,” of the chin protector because of improved stability of the helmet 10 on the wearer's head during play. Thus, the retention and proper positioning of the helmet 10 upon impact(s) is improved.
- the helmet 10 features an energy attenuating faceguard mounting system 14 , including the faceguard 35 and means for dynamically connecting the faceguard 35 , which interact to reduce impact forces received on the faceguard 35 and transmitted to the helmet shell 11 .
- the energy attenuating faceguard mounting system 14 does not include a connection point with a front bumper 202 at the brow region 11 c of the shell 11 for the faceguard 35 . In other words and as shown in FIGS.
- the helmet 10 lacks a component that is connected between the front region of the shell and the faceguard.
- the dynamic faceguard connecting means comprises a helmet shell connection segment that is movable relative to the remaining shell 11 and that receives a coupler for securement of the faceguard 35 .
- the helmet shell connection segment can be integrally formed within the shell 11 , for example in the ear flap 12 .
- the helmet shell connection segment can be formed separately and then operatively joined to the shell 11 .
- the shell 11 can include a generally circular opening that receives and operatively connects with the helmet shell connection segment.
- the helmet shell connection segment can function similar to a butterfly valve where the connection segment includes a disc that is secured to the shell 11 by a rod and a peripheral region 38 of the faceguard 35 is secured to the rod either directly or via an actuator.
- a portion of the connection segment for example the disc, moves or rotates relative to the remaining shell 11 which allows for movement of the peripheral faceguard region 38 .
- the helmet shell connection segment can flex inward and/or outward when the impact force is applied to the faceguard 35 .
- the dynamic faceguard connecting means comprises a plunger assembly coupled to the helmet shell 11 wherein a first plunger component moves relative to the shell 11 (e.g., substantially normal to the shell 11 ) when an impact force is applied to the faceguard 35 .
- the movement of the plunger assembly facilitates movement of the faceguard 35 , including a peripheral faceguard region 38 , when the impact force is received by the faceguard 35 .
- the dynamic faceguard connecting means comprises the dynamic faceguard connector 16 . Referring to FIGS. 1-3A and as explained below, the helmet 10 includes two dynamic connectors 16 , one on each side region 24 of shell 11 positioned slightly above the ear opening 12 a.
- the helmet 10 also includes a pair of lower (non-dynamic) connector 15 positioned on the jaw flap 13 near the lower shell edge 22 .
- the helmet 10 may include a greater number of dynamic connectors 16 , for example, four dynamic connectors 16 wherein the helmet 10 has a pair of upper dynamic connectors 16 and a pair of lower dynamic connectors 16 .
- the faceguard 35 comprises a plurality of elongated bar members 39 , which may be formed of any suitable material having the requisite strength and durability characteristics to function as a football helmet faceguard.
- the members 39 may be preferably formed of a metallic material, such as steel or titanium, and as is known in the art, the bar members 39 may be provided with a durable coating (e.g., plastic coating). Additionally, the bar members 39 may be of a solid or tubular cross-sectional configuration. Alternatively, bar members 39 may be formed of a suitable plastic material, including a fiber reinforced plastic resin, having the requisite strength and durability characteristics to perform the functions of a football helmet faceguard.
- the faceguard connectors 15 , 16 encircle portions of the bar members 39 of the faceguard 35 .
- the faceguard connectors 15 , 16 are shown with a quick release coupler 50 , which is described in more detail in pending U.S. patent application Ser. No. 12/082,920, which is incorporated herein by reference.
- an elongated fastener such as a threaded screw, may be employed with the faceguard connectors 15 , 16 to secure the faceguard 35 to the helmet 10 .
- a pair of dynamic faceguard connectors 16 and the quick release coupler 50 connect an upper portion of the faceguard 35 to an interface area 11 e of the shell 11 at the ear flap 12 and over a superior (or frontal) portion of the helmet wearer's temporal lobe.
- the interface area 11 e is outwardly raised or offset relative to the adjacent portion of the shell 11 .
- opposed ends of the thickened segment 11 g adjoin the interface areas 11 e to provide a continuous, uninterrupted frontal offset of the shell 11 .
- the interface area 11 e has significant dimensions such that it extends from the interior frontal edge 11 b rearward past a shell opening 200 (that receives an extent of the coupler 50 ). Focusing on FIG. 3A , a rear edge of the interface area 11 e is positioned rearward of the faceguard 35 , the upper faceguard connector 16 , and the lower faceguard connector 15 . Preferably, the faceguard connector 16 is positioned adjacent the interior edge 11 b of the frontal shell opening 11 a and below an upper edge 11 d of the frontal opening 11 a . More preferably, the faceguard connector 16 is positioned above the ear opening 12 a and the jaw flap 13 .
- the dynamic faceguard connectors 16 define an uppermost faceguard securement point located over the helmet wearer's superior temporal lobe and lateral to the brow region 11 c of the shell 11 .
- the uppermost faceguard securement point is also below the frontal opening upper edge 11 d and upper substantially horizontal bar 52 a of the faceguard 35 , and above the ear opening 12 a and jaw flap 13 .
- At least one horizontal upper bar 52 a of the faceguard 35 extends between the dynamic faceguard connectors 16 and the opposed faceguard securement points provided by the dynamic connectors 16 .
- a second substantially horizontal upper bar 52 b is proximate and below the upper bar 52 a and extends between transverse intermediate bars 52 f.
- the transverse intermediate bars 52 f are omitted and the second upper bar 52 b is joined with the first upper bar 52 a.
- Both of the upper bars 52 a, b are offset from the shell 11 and do not contact the brow region 11 c (or front region) of the shell 11 .
- the upper bars 52 a, b extend between the connectors 16 and along the brow region 11 c without connecting to the brow region 11 c.
- at least the uppermost bar 52 a spans frontal opening 11 a and the distance between the dynamic connectors 16 without connecting to the nameplate (or front bumper) 202 affixed to the brow region 11 c. Accordingly, the brow (front) region 11 c of the shell 11 lacks a faceguard connector.
- the upper bars 52 a, b have a length with a curvilinear configuration that substantially corresponds to the curvilinear configuration of the brow region 11 c of the shell 11 .
- the offset between the upper bars 52 a, b , and the shell 11 forms a gap G or standoff (see FIGS. 5, 6 and 6A ) that is generally greater than 0.25 inch, and preferably between 0.25 inch and 0.5 inch.
- conventional helmets include a faceguard that is secured to the helmet by at least one connector, typically a pair of connectors, coupled to the helmet's brow region whereby at least one upper bar, typically two upper bars contact the brow region.
- Conventional faceguards are further secured by at least one additional pair of connectors, each being coupled to an earflap of the shell.
- the dynamic connector 16 includes the quick release coupler 50 that extends through a grommet 90 positioned within a shell opening 200 .
- the coupler 50 is received by a fastening washer 91 that extends through both the grommet 90 and the shell opening 200 .
- the quick release coupler 50 also comprises sleeve body 92 , an actuator or pin 93 , and a spring 94 .
- the sleeve body 92 receives the actuator 93 to removably secure the dynamic connector 16 to the shell 11 .
- the quick release coupler mechanism 50 is employed to secure the dynamic faceguard connectors 16 to the shell 11 .
- the coupler mechanism 50 that provides for rapid attachment and detachment of the connectors 16 and the faceguard 35 from the shell 11 without the deliberate and time-consuming use of a screwdriver (or cutting tool for removal).
- the releasable coupler mechanism 50 extends through the opening 120 in the bracket 100 and into a shell opening 200 .
- the coupler mechanism 50 further includes a head, a washer, ball, and a retaining notch. The coupler 50 is retained in a use position (see FIG. 9 ) by the engagement between the ball, the retaining notch and the distal end segment of the pin.
- an inwardly directed actuation force is applied to the pin by an object.
- the dynamic faceguard connector 16 comprises a bracket 100 with a movable segment and a stable segment that are operatively connected to each other to facilitate movement of the faceguard 35 when an impact force is applied thereto.
- the bracket's movable segment is the peripheral bracket segment 113 and the stable segment is the internal segment 114 .
- the bracket 100 also includes a band or strap member 102 that wraps around a peripheral bar member 52 c that extends downwardly and transversely from the upper bar member 52 a.
- the lower faceguard connector 15 discussed in greater detail in pending U.S. patent application Ser. No.
- bracket 15 a also comprises a bracket 15 a with a band that encircles the periphery of a peripheral member bar 52 d that extends upwardly and transversely from a lower bar member 52 e.
- the band 102 of bracket 100 forms a receiver 104 that encircles the bar 52 c, wherein the receiver 104 provides a single encircling point for the faceguard bar 52 c.
- the receiver 104 is oriented substantially perpendicular to the longitudinal axis of the bracket 100 .
- the bracket 100 additionally includes a rear flange 106 that includes the band 102 and the receiver 104 , and a frontal tab 108 . As shown in FIG.
- the flange 106 also includes an indentation 106 a located approximately at a mid-point of the width of the flange 106 .
- a first side rail 110 and a second side rail 112 extend between the flange 106 and the frontal tab 108 .
- the flange 106 , the frontal tab 108 , and the side rails 110 , 112 collectively comprise the peripheral segment 113 of the bracket 100 .
- the bracket 100 has a “clam-shell” design such that it opens about the receiver 104 and flange 106 to receive the faceguard bar 52 c.
- the bracket 100 has an outer half or portion 122 and an inner portion 124 , as described in more detail below, that meet at a rear seam extending along the receiver 104 .
- the peripheral segment 113 of the outer portion 122 includes an outer side rail segment 110 a of the first side rail 110 , an outer side rail segment 112 a of the second side rail 112 , and an outer segment 108 a of the frontal tab 108 .
- the peripheral segment 113 of the inner portion 124 includes an inner side rail segment 110 b of the first side rail 110 , an inner side rail segment 112 b of the second side rail 112 , and an inner segment 108 b of the frontal tab 108 .
- the first side rail 110 comprises the outer side rail segment 110 a and the inner side rail segment 110 b;
- the second side rail 112 comprises the outer side rail segment 112 a and the inner side rail segment 112 b; and
- the frontal tab 108 comprises the outer segment 108 a and the inner segment 108 b.
- the connector bracket 100 includes a hinged internal segment 114 that enables the bracket 100 to flex when impact forces are applied to the faceguard 35 .
- the peripheral segment 113 flexes or moves relative to the internal segment 114 when an impact force F is applied to the face guard 35 .
- the hinged segment 114 has an outer portion 114 a associated with the outer portion 122 , and an inner portion 114 b associated with the inner portion 124 .
- the hinged internal segment 114 connects to the frontal tab 108 , and includes a frontal recess 115 at the interface with the frontal tab 108 .
- the frontal recess 115 defines a hinge line 115 a for the internal segment 114 , wherein both are substantially perpendicular to the longitudinal axis of the bracket 100 .
- a rear extent of the hinged internal segment 114 that is opposite the frontal recess 115 is free or not connected to the first side rail 110 and the second side rail 112 .
- the hinged internal segment 114 does not connect to the flange 106 and therefore, the hinged internal segment 114 and the flange 106 move independently of each other.
- a gap 116 is formed between the hinged internal segment 114 , the first side rail 110 , the second side rail 112 , and the peripheral flange 106 , namely the internal walls of same.
- the gap 116 includes opposed recesses 118 a, 118 b disposed adjacent the frontal tab 108 .
- the opposed recesses 118 a, 118 b separate the hinged internal segment 114 from the first side rail 110 and the second side rail 112 , allowing motion of the side rails 110 , 112 relative to the hinged internal segment 114 .
- the gap 116 has curvilinear segments as shown in FIG. 3A .
- the curvilinear segments of the gap 116 are complimentary to a profile of a periphery of the hinged internal segment 114 .
- the hinged internal segment 114 further comprises an opening or bore 120 .
- the opening 120 is adapted to receive an elongated fastener, such as coupler 50 , to secure the bracket 100 and the faceguard 35 to the shell 11 .
- the hinged internal segment 114 additionally has a countersink 121 , aligned with the opening 120 , to enable a head portion of the fastener to reside below the outer portion 122 .
- the outer bracket portion 122 defines an inclined outer wall surface 126 of the outer portion 122 that extends between the front tab 108 and the rear flange 106 .
- the inclined outer wall surface 126 is configured to allow for the inclusion of text, such as a company identifier or logo.
- the inner bracket portion 124 including the inner first side rail segment 110 b , the second outer side rail segment 112 b, and the frontal tab inner segment 108 b, defines a generally planar inner wall surface 128 .
- the internal portion 114 b of the inner portion 114 has an inner surface 114 d that is slightly recessed from the inner wall surface 128 .
- an outer surface 114 c of the outer segment 114 a of the internal segment 114 is recessed from the outer wall 126 of the outer portion 122 thereby forming an offset K.
- an internal cavity 117 is formed between the internal segment 114 the internal portions of the side rails 110 , 112 and the flange 106 .
- the offset K varies over the length of the bracket 100 , in that the offset K is smaller near the frontal tab 108 and the offset K is larger near the peripheral flange 106 .
- the offset K facilitates pivotal movement of the peripheral segment 113 relative to the internal segment 114 upon an impact to the faceguard 35 .
- one of the outer portion 122 and the inner portion 124 has a protrusion 130 that interacts with a recess 132 formed in the other of the outer portion 122 and the inner portion 124 , preferably at a location adjacent the hinge line of the internal segment 114 .
- the bracket's movable segment is the peripheral segment 113 and the stable segment is the internal segment that are operatively connected.
- the peripheral segment 113 is fixed and internal segment 114 is movable when an impact force is applied to the faceguard 35 , as discussed below.
- the bracket 100 includes a front segment and a rear segment, wherein one of the segments moves when an impact force is applied to the faceguard 35 and the other of the segments remains stable and secured to the shell 11 .
- FIGS. 6 and 9 show the energy attenuating faceguard mounting system 14 in an installed or first position P 1 (and prior to any impact to the helmet 10 ), wherein the faceguard 35 is dynamically connected to the helmet 10 by the connectors 16 .
- the first position P 1 reflects the connector 16 position before an impact is applied to the faceguard 35 , or the post impact state where energy from an impact has been fully absorbed and dissipated by the energy attenuating faceguard mounting system 14 .
- upper bar members 52 a, b extend between the connectors 16 but do not connect with the helmet 10 at or near the shell's brow region 11 c or front bumper 202 , thereby providing the gap G.
- the inner wall 128 of the inner portion 124 is spaced a distance D 1 from the outer surface 18 of the shell 11 at the interface area 11 e.
- the distance D 1 also represents the distance between the outer shell surface 18 and the inner first and second side rail segments 110 b, 112 b.
- the internal segment 114 remains substantially stable, but the flange 106 and the side rails 110 , 112 of the peripheral segment 113 flex relative to the internal segment 114 .
- this movement occurs in two directions—outward from the shell 11 , and inward towards the shell 11 —which provides the connector 16 with dynamic characteristics upon an impact to the faceguard 35 .
- the faceguard 35 is shown in the Figures as single structure formed from a plurality of intersecting bar members.
- the faceguard 35 comprises distinct portions, such as an upper portion and a lower portion wherein each portion includes a plurality of intersecting bar members.
- This faceguard 35 configuration can result from the removal of the lower vertical bar members 39 (see FIG. 1 ) that extend from the lower portion to the upper portion. Assuming the resulting upper portion of the faceguard is secured to the helmet shell 11 by the dynamic connectors 16 , the upper faceguard portion will behave in a manner consistent with that described below for both on-center and off-center impacts.
- FIGS. 7 and 10 show the energy attenuating faceguard mounting system 14 in a second position P 2 wherein an “on-center” impact force F, that is substantially lateral, is applied to a center point 36 of the faceguard 35 .
- the on-center impact F occurs within thirty degrees) (30°) of the faceguard center point 36 , which may be defined by a substantially vertical center bar member 37 .
- the center bar member 37 is omitted and the center point 36 is located between two other vertical bar members, for example vertical bars in the upper or lower portion of the faceguard 35 .
- the peripheral flange 106 , the first side rail 110 and the second side rail 112 move away from the outer shell surface 18 at the interface area 11 e, while the internal segment 114 remains stable due to the securement with the helmet shell 11 provided by the coupler 50 .
- the peripheral flange 106 , the first side rail 110 and the second side rail 112 move relative to the internal segment 114 along the hinge line 115 a .
- a distance D 2 (where D 2 exceeds D 1 ) exists between the outer shell surface 18 and the inner wall 128 of the inner portion 124 .
- the distance D 2 also represents the distance between the outer shell surface 18 and the inner first and second side rail segments 110 b, 112 b .
- FIG. 7 indicates that both faceguard connectors 16 will behave similarly and experience the same amount of flex during an on-center impact.
- an impact force F that is not purely on-center but that falls within 30 degrees of on-center (or within the total 60 degree window) may cause one connector 16 to behave slightly differently than a second connector 16 .
- an impact force that is applied 10 degrees off-center on a center left portion of the face guard 35 will cause the helmet's left connector 16 a to flex less than the helmet's right connector 16 b . Therefore, the distance D 2 between the left connector 16 a and the outer shell surface 18 at the interface area 11 e is less than the distance D 2 between the right connector 16 b and the outer shell surface 18 at the interface area 11 e.
- the movement of the faceguard 35 provided by the dynamic connectors 16 dissipates energy received by the faceguard 35 from the on-center impact, and temporarily reduces the gap G between the faceguard upper bars 52 and the shell 11 (as compared to the gap G in the first position P 1 of FIG. 6 ). Under most impact conditions, the gap G is temporarily reduced but not entirely eliminated, whereby the transmission of faceguard impact forces to the shell front 21 is reduced. Due to the nature of the faceguard impact, the dynamic faceguard connector 16 experiences both inward and outward movement relative to the shell 11 during an on-center impact. The extent of this dual movement varies with a number of impact factors, including the speed of the impact, the duration of the impact and the faceguard location of the impact.
- the connector bracket 100 rapidly moves (or flexes) outward relative to the shell 11 and then inward relative to the shell 11 several times per impact.
- the connector's flange 106 and side rails 110 , 112 oscillate back and forth about the stable internal segment 114 until the impact energy is sufficiently dissipated.
- the bar members 39 of the faceguard 35 including the uppermost bars 52 a, b elastically deform upon an impact.
- the faceguard 35 elastically deforms such that the opposed peripheral faceguard regions 38 move outward or away from the helmet shell 11 .
- the dynamic faceguard connectors 16 a, b facilitate and/or enable movement of the peripheral faceguard regions 38 that is substantially normal or substantially perpendicular to the outer shell surface 18 at the interface area 11 e when an on-center impact force F is applied to the faceguard 35 .
- FIGS. 8, 9A, and 10 show the energy attenuating faceguard mounting system 14 in a third position P 3 wherein an “off-center” impact force F, that is substantially lateral, is applied to the faceguard 35 .
- the off-center impact F occurs to the side of the face guard 35 beyond thirty degrees (30°) of the faceguard center point 36 .
- the off-center impact F occurs at a left portion of the faceguard 35 , between a lowermost bar 52 e and the uppermost bar 52 a. Due to the off-center impact force F, the gap G on the left side of the face guard 35 is temporarily eliminated.
- the gap G on the right side of the face guard 35 is similar to that for the first position P 1 (see FIG.
- this gap G may slightly, temporarily increase.
- the left faceguard connector 16 a and the left peripheral faceguard portion 38 a compresses towards the interface area 11 e of the helmet shell 11
- the right faceguard connector 16 b and the right peripheral faceguard portion 38 b flexes away from the interface area 11 e of the helmet shell 11 .
- the faceguard connector 16 and the peripheral faceguard portion 38 located on an opposite side of the faceguard as the off-center impact force F initially moves outward and substantially normal relative to the interface area 11 e of the shell 11 while the faceguard connector 16 and the peripheral faceguard portion 38 on the same side as the impact force F initially moves inward and substantially normal relative to the interface areal le of the shell 11 .
- the faceguard connectors 16 behave differently which demonstrates the dynamic nature of the connector 16 .
- the right connector 16 b including the bracket 100 , behaves in the manner described above and shown in FIG. 10 .
- the bracket 100 of the left connector 16 a initially moves towards the interface area 11 e of the helmet shell 11 and depending upon the magnitude and duration of the impact F, the inner bracket wall 128 makes contact with the outer shell surface 18 . In this manner, the distance D 3 between the outer shell surface 18 and the inner wall 128 of the inner portion 124 is temporarily eliminated. The bracket 100 of the left connector 16 a then moves away from the shell outer surface 18 . When the off-center impact force F has a lesser magnitude and/or duration, the inner portion 124 of the connector 16 a may not contact the outer shell surface 18 and the distance D 3 is less than D 2 or D 1 . Thus, the faceguard connector 16 on the same side of the faceguard 35 as the off-center impact F initially moves towards the helmet shell 11 , and the connector 16 on the other side of the faceguard 35 initially moves away from the helmet shell 11 .
- an on-center impact force F applied in a vertically downward direction to the faceguard 35 cause the dynamic faceguard connectors 16 to flex outward relative to the shell 11 .
- This behavior is similar to when a lateral impact force F is applied on-center to the faceguard 35 .
- an on-center impact force F applied in a vertically upward direction (towards the crown 19 ) to the faceguard 35 cause the dynamic faceguard connectors 16 to flex inward relative to the shell 11 .
- Testing the inventive helmet 10 involved mounting it on a Hybrid III headform that is coupled to a test table that is movable along a single axis.
- a ram is moved axially along the single axis in the same direction that the moveable table may travel.
- the ram was moved at different speeds, such as, for example, 5 mis, 7 mis, and/or 9 mis, to deliver a force to the faceguard 35 of the helmet 10 .
- Sensors within the headform measure lateral acceleration as well as severity index of the impact of the ram with the helmet 10 . This testing has shown that the helmet 10 and its energy attenuating facemask mounting system 14 significantly reduces both lateral acceleration and severity index of impacts delivered by the ram to the faceguard 35 over a variety of impact speeds.
- FIGS. 5A and 5B show a front bumper or nameplate 202 affixed to the brow region 11 c of the shell 11 by internal fasteners that are not externally visible.
- the bumper 202 has a curvilinear configuration that substantially corresponds to the configuration of the brow region 11 c, and facilitates the positioning and securement of the internal padding assembly 300 .
- Fasteners 204 a, 204 b pass through openings 11 f in the shell 11 and bumper opening 215 and are received by respective nuts 206 a, 206 b that are secured within an internal pocket 205 formed in the bumper 202 .
- the fastener 204 a, 204 b extends through only a portion of the bumper 202 and no fastener extends through the entirety of the bumper 202 .
- the pockets 205 are in an opposed relationship, wherein each pocket 205 has an access slot 207 aligned with the periphery of the bumper 202 , such as a sidewall 202 a or a top wall 202 b.
- the slot 207 is formed in the sidewall 202 a of the bumper 202 and leads to the pocket 205 and the bumper opening 215 , which are both positioned a distance from the sidewall 202 a.
- the internal pocket 205 retains the nuts 206 a, 206 b as the helmet 10 lacks any connectors for the upper bar 52 of the faceguard 35 at the brow region 11 c of the shell 11 .
- the bumper 202 also includes a lower groove 203 that is defined by an internal flange 208 and that engages the frontal opening upper edge 11 d of the shell 11 to facilitate engagement thereto. As shown in FIGS. 5A and 5B , a first inner wall 202 c and a second inner wall 202 d of the bumper 202 resides adjacent the outer surface 18 of the shell 11 and the flange 208 is positioned between the frontal opening upper edge 11 d and a front pad 302 of the internal pad assembly 300 .
- the bumper 202 contains an outer surface or panel that allows for indicia, such as the manufacturer of the helmet 10 , or the name of a team of the wearer 500 .
- the helmet 10 lacks any externally visible fastener hardware at the brow region 11 c.
- conventional helmets utilize external fastening hardware to secure the faceguard to the bumper and helmet, which reduces the aesthetic appearance of the conventional helmet.
- FIGS. 11-16 show the shell 11 having a transition region TR, where the thickness of the shell 11 varies from a first thickness at the front portion 21 of the shell 11 to the rear portion 20 of the shell 11 .
- the transition region TR is a transverse band that extends between the symmetric left and right side regions 24 a,b of the shell 11 , preferably rearward of the ear openings 12 .
- the transition region extends from the lower shell edge 22 of the left shell portion 22 a to the lower shell edge 22 of the right shell portion 22 b.
- the transition region TR intersects and includes the raised central band 60 that extends from the front shell portion 21 and along the crown 19 .
- the transition region TR is roughly 1 inch wide and the thickness of the shell 11 transitions from about 0.125 inches in the front shell portion 21 to about 0.100 inches in the rear shell portion 20 . This reduction in width reduces the weight of the helmet 10 , and the amount of raw material used to form the shell 11 .
- FIG. 12 provides a frontal view of the helmet 10 , with a central axis A-A dividing the shell 11 into the left region 24 a and right region 24 b.
- the shell 11 includes an internal rib extending along the inner shell surface 17 from the rear shell portion 20 upward through the crown 19 and towards the front shell portion 21 .
- Section plane 13 - 13 corresponding to the cross-section of FIG.
- the shell 11 has a frontal shell segment with a first thickness T 1 forward of the transition region TR and a rear shell segment with a second thickness T 2 rearward of the transition region TR, wherein the first thickness T 1 exceeds the second thickness T 2 .
- the transition region TR extends between the two thicknesses T 1 , T 2 .
- the first thickness T 1 is defined between an inner frontal shell surface 17 a and the outer shell surface 18
- the second thickness T 2 is defined between an inner rear shell surface 17 b and the outer shell surface 18 .
- the inner frontal shell surface 17 a has a first radius of curvature 212 and a tangential arrow 212 a thereof, as well as a second radius of curvature 214 and a tangential arrow 214 a thereof.
- the transition region TR has a radius of curvature 216 (see FIG. 16 ) that is tangential to both the frontal shell surface 17 a and the rear shell surface 17 b proximate the arrows 212 a, 214 a, respectively
Abstract
A protective sports helmet that includes an energy attenuating faceguard connection system, which includes at least one connector that secures the faceguard to the helmet shell without a connection point in the shell's brow region. The lack of a brow region connection point results in a gap or clearance between the faceguard and the shell that has a functional interplay with the connector upon an impact to the faceguard. In general terms, when a substantially on-center impact to the faceguard occurs, the faceguard is displaced towards the shell and the connector bracket flexes outward relative to the helmet shell to help dissipate impact energy.
Description
- This Application is a continuation of pending U.S. patent application Ser. No. 15/076,106, which is a continuation of U.S. patent application Ser. No. 13/068,104, which claims the benefit of Provisional Patent Application No. 61/343,567, all of these applications which are incorporated herein by reference and made a part hereof. U.S. Pat. No. 8,813,269 and U.S. Provisional Patent Application No. 60/923,603 are incorporated herein by reference and made a part hereof.
- 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 an energy attenuating faceguard mounting system that reduces impact forces received by a faceguard secured to the helmet.
- 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 faceguard is rigidly secured to the shell by a plurality of connectors, whereby the faceguard can sustain a number of impacts during the course of play while remaining connected to the shell. Most faceguards include a plurality of intersecting and/or overlapping bars that form openings through which the wearer views the field of play. With conventional helmets, the upper faceguard bars directly contact the lower frontal portion of the helmet shell, which is referred to as the “brow region” of the shell. This direct contact results from the use of a pair of connectors secured to the brow region of the helmet shell. Additional connectors are employed to secure the faceguard to the side portions of the helmet shell. Conventional faceguard connectors are purposely designed to avoid flexing when the faceguard receives an impact force.
- One existing faceguard connector is a plastic U-shaped strap member that has a receiver portion that encircles a bar of the faceguard. This strap connector includes a tab portion, wherein a threaded fastener, such as a screw, extends through the tab portion and into the shell to secure the connector and the faceguard to the helmet. Typically, these U-shaped strap connectors are found above the brow region of the shell and along each ear flap to join the faceguard to the shell. A second existing faceguard connector is disclosed in U.S. Pat. No. 6,934,971, which is owned by Riddell Inc., the assignee of the present application. That connector, marketed under the Isolator System brand name, includes a nut, a bushing, a grommet, a rectangular bracket and a threaded fastener (screw). The bracket includes a first channel that receives a first bar of the faceguard and a second channel that receives a second bar, wherein the faceguard bars are positioned between the shell and the bracket. The fastener extends through the bracket and the shell and is received by the nut (residing within the shell) to couple the faceguard to the shell. The threaded fastener is employed to secure the connector to the shell and as a result, a rotational force is applied to tighten for securement and loosen the fastener to permit removal of the bracket and faceguard. While such conventional faceguard connectors provide a number of benefits, they nevertheless have certain limitations. For example, adjusting and/or removing the faceguard from the shell can be difficult and time consuming. Because a threaded fastener is utilized, rotation of a flat-blade or Phillips screwdriver is required to loosen the fastener to allow for removal of the bracket and the faceguard. Removal of a faceguard becomes necessary when the player is injured or the player's faceguard is damaged and involves unscrewing the fastener to allow for removal of both the connector and the damaged faceguard. After the damaged faceguard is removed, a replacement faceguard is secured to the helmet with the fastener and connector. This removal and replacement process is time consuming and requires that the player having the damaged equipment to be removed from play until the process is completed. The unavailability of the player to participate in further play is detrimental to the team, especially if the player plays an essential position such as quarterback.
- One additional limitation of the use of a faceguard connector above the brow region of the shell is the transmission of faceguard impact forces. Because the faceguard is in direct contact with the shell, a significant extent of a faceguard impact force is transmitted from the faceguard to the shell. Depending upon its severity and magnitude, an extent of the impact force may be transmitted through the internal padding assembly to the wearer of the helmet.
- 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.
- The present invention is directed to a protective sports helmet that includes a number of improvements intending to increase the protective nature of the helmet. For example, the helmet features an energy attenuating faceguard mounting system, which includes at least one connector that secures the faceguard (or face mask) to the helmet shell without a connection point to the shell's brow region. The lack of a brow region connection point results in a gap or clearance between the faceguard and the shell that has a functional interplay with the connector upon an impact to the faceguard.
- While it is the desire and goal that a football helmet, and other types of protective helmets, prevent injuries from occurring, it should be noted that as to the helmet of the present invention, as well as prior art helmets, due to the nature of contact sports (including football), no protective equipment or helmet 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 the football player uses his football helmet in an improper manner, such as to butt, ram, or spear an opposing player, which is in violation of the rules of football and severe head and/or neck injuries, paralysis, or death to the football player, as well as possible injury to the football player's opponent can result. 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 completely prevent head 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.
- 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 perspective view of an embodiment of a sports helmet having an energy attenuating system of the invention, the system including a faceguard and a dynamic faceguard connector assembly; -
FIG. 1A is a perspective view of the helmet ofFIG. 1 , where the internal padding of the sport helmet has been removed; -
FIG. 1B is an elevated perspective view of the helmet ofFIG. 1 ; -
FIG. 2 is a front view of the helmet ofFIG. 1 , including an alternative faceguard design; -
FIG. 2A is a front view of the helmet ofFIG. 1 ; -
FIG. 3 is a side view of the helmet ofFIG. 1 , including a wearer of the helmet being partially shown in phantom lines; -
FIG. 3A is a side view of a portion of the helmet ofFIG. 1 showing the energy attenuating system of the helmet; -
FIG. 4A is a perspective view of the dynamic faceguard connector of the energy attenuating system of the helmet ofFIG. 1 ; -
FIG. 4B is a side view of the dynamic faceguard connector of the energy attenuating system of the helmet ofFIG. 1 ; -
FIG. 4C is a top view of the dynamic faceguard connector of the energy attenuating system of the helmet ofFIG. 1 -
FIG. 5A is a perspective view of a nameplate used with the helmet ofFIG. 1 ; -
FIG. 5B is a cross-sectional view of the nameplate ofFIG. 5a , showing the nameplate mounted to the helmet and a gap G between the faceguard member and the helmet; -
FIG. 6 is a top view of the helmet ofFIG. 1 , showing the energy attenuating system of the helmet in an installed position; -
FIG. 6A is a partial top view of the helmet ofFIG. 1 showing the energy attenuating system of the helmet in the installed position; -
FIG. 7 is a partial top view of the helmet ofFIG. 1 showing the energy attenuating system of the helmet wherein a generally on-center force F is applied to the faceguard; -
FIG. 8 is a partial top view of the helmet ofFIG. 1 showing the energy attenuating system of the helmet wherein a generally off-center force F is applied to the faceguard; -
FIG. 9 is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet ofFIG. 6A and shown within dotted lines therein; -
FIG. 9A is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet ofFIG. 8 and shown within dotted lines therein; -
FIG. 10 is a cross-sectional view of the dynamic faceguard connector assembly affixed to the helmet ofFIGS. 7 and 8 and shown within dotted lines therein; -
FIG. 11 is a side view of the helmet ofFIG. 1 showing a transitional region of the shell; -
FIG. 12 is a front view of the helmet shell ofFIG. 1 ; -
FIG. 13 is a cross-sectional view of the shell portion of the helmet taken through line 13-13 ofFIG. 12 ; -
FIG. 14 is a partial cross-sectional view of the shell portion of the helmet shown within dotted lines ofFIG. 13 ; -
FIG. 15 is a partial sectional view of a transitional region of the shell portion of the helmet showing the curvature of a front portion of the shell and a rear portion of the shell; -
FIG. 16 is a partial sectional view of a transitional region of the shell portion of the helmet showing the curvature of the front portion of the shell, the rear portion of the shell, and a transitional portion of the shell; and, -
FIG. 17 is a rear view of the helmet ofFIG. 1 . - 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.
- 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 to generally include: anouter shell 11 with anear flap 12 and ajaw flap 13, an energy attenuatingfaceguard mounting system 14 comprising afaceguard 35 that spans a frontal shell opening 11 a and at least onedynamic faceguard connector 16, and aninternal padding assembly 300. Theouter shell 11 includes afrontal opening 11 a defined by an arrangement of edges including an interiorfrontal edge 11 b (seeFIG. 3A ) and an upperfrontal edge 11 d (seeFIGS. 3, 3 a), where the upperfrontal edge 11 d of thefrontal opening 11 a can also be considered a lower frontal edge of theshell 11. Theouter shell 11 also includes abrow region 11 c (seeFIG. 1A ) that resides above the upperfrontal edge 11 d and that overlies a brow of thewearer 500 of thehelmet 10, when thehelmet 10 is worn (seeFIG. 3 ). Theouter shell 11 also includes a thickenedsegment 11 g that extends laterally along the upperfrontal edge 11 d and into aninterface area 11 e (seeFIGS. 3, 5B, 12 and 13 ). As shown inFIGS. 5B and 13 , anangled transition wall 11 h leads to the thickenedsegment 11 g. Focusing onFIGS. 1B and 12 , the thickenedsegment 11 g and theinterface area 11 c are raised relative to the adjacent portion of theshell 11. Theouter shell 11 is preferably made of a 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. Alternatively, the shell is made from a fiber reinforced plastic resin, wherein carbon fibers are utilized.Outer shell 11 has an inner wall surface 17 (FIG. 12 ) and anouter wall surface 18. Referring toFIGS. 1-3 , theshell 11 further includes acrown 19, a back or rear 20, a front 21, alower edge surface 22, and two side regions 24 (which include theear flap 12 and jaw flap 13). As is known in the art, and as will be hereinafter described in greater detail,shell 11 is adapted to receive thehead 525 of awearer 500 of thehelmet 10. Referring toFIG. 3 , the wearer orplayer 500 has a jaw or mandible 526 (FIG. 3 ) that generally comprises a substantiallyvertical ramus portion 527, a body orside portion 528, and a frontal or mental protruberance orchin portion 529. As shown inFIG. 3 , thebody portion 528 extends between theramus portion 527 and thechin 529. Theramus portion 527 includes an upper segment with coronoid and condyloid processes that are proximate and forward ofears 530 ofwearer 500. - With reference to
FIGS. 1, 1A, 3, 11 and 17 , eachside region 24 of theshell 11 includes anear flap 12, which is adapted to generally overlie an ear 530 (FIG. 3 ) and portion of a cheek of thewearer 500. Eachear flap 12 generally extends downwardly from theside region 24 to thelower edge surface 22 ofshell 11. Eachear flap 12 includes ajaw flap 13 that extends from itscorresponding ear flap 12 forwardly toward thefront 21 of theshell 11. As seen inFIG. 3 , thejaw flap 13 is adapted to generally extend to overlie a portion of thebody portion 528 of thejaw 526 of thewearer 500 of thehelmet 10. As shown inFIG. 3 ,jaw flap 13 extends forwardly to overlie a forwardly disposed portion of thejaw 526 disposed toward thechin 529 ofwearer 500. Thejaw flap 13 extends forwardly enough to overlie a portion of the side of thechin 529 ofwearer 500, but not theentire chin 529. Thejaw flap 13 does not need to extend to completely cover thechin 529 of thewearer 500, but it is contemplated that it may extend to completely cover thechin 529 in some embodiments, or based on the specific anatomy of some wearers. It is further contemplated that thejaw flap 13 will not cover any portion of thechin 529 of thewearer 500 in other embodiments, or based on the specific anatomy of some wearers. In this regard, it should be noted thathelmets 10 of the present invention are generally made withouter shells 11 of varying sizes, dependent upon the size of the head of the particular wearer of the helmet. It is also noted that players are fitted for helmets by trained personnel in accordance with written fitting guidelines. InFIG. 3 , a properly-sized helmet 10 is shown superimposed upon what is believed to be an average size head of a wearer of thehelmet 10, wherebyjaw flap 13 is shown to generally overlie theentire ramus 527 of thejaw 526 and at least some of thebody portion 528 of thejaw 526, including a forwardly disposed portion ofjaw 526 adjacent thechin 529 ofwearer 500, including overlying at least some portion of the side of thechin 529 ofwearer 500. SinceFIG. 3 is not a representation of all sizes of heads and all types of chin structures, such as chins which may greatly extend outwardly away from the head of the wearer, it should be understood that it is perhaps possible that someone wearing ahelmet 10 in accordance with the present invention may have a larger or smaller side portion of his or her chin extending outwardly further beyond the outer periphery ofjaw flap 13. When thehelmet 10 is properly sized and fitted to thewearer 500, it is believed thatjaw flap 13 will overlie some portion of thebody 528 of thejaw 526 of virtually all wearers ofhelmets 10. - As shown in the Figures, the
helmet shell 11 has an arrangement of complex contours. Referring toFIGS. 1, 1A, 1B, 2, 2A, 3, 11 and 12 , theshell 11 has a raisedcentral band 60 extending rearward from thefront shell portion 21 and along thecrown 19. The raisedcentral band 60 has an initial frontal width that is reduced as theband 60 extends rearward through thecrown 19. In one embodiment, the initial frontal width is approximately 5 to 6 inches. Also, theband 60 has an initial frontal height defined by a beveled (or inclined) sidewall 60 a that is reduced along theband 60, whereby a rear segment of theband 60 is substantially flush with theouter surface 18 of theshell 11, preferably being flush rearward of a midpoint of thecrown 19. As shown inFIGS. 1, 1A, 1B, 2, 2A, 3 , a pair of opposed front raisedlateral ridges 62 extend transversely and substantially upward from theband 60 and towards theear flap 12. As shown inFIG. 1 , the raisedlateral ridge 62 has an initial frontal height defined by a firstbeveled sidewall segment 62 a that extends laterally and downwardly from thesidewalls 60 a of theband 60. Also, as shown inFIGS. 1, 1A, 1B, 2, 2A, 3 , the raisedlateral ridges 62 have a secondbeveled sidewall segment 62 b that extends laterally and upwardly from the firstbeveled sidewall segment 62 a and towards theear flap 12. Due to its upward extension, a midpoint of thesecond sidewall segment 62 b is approximately 1.5 to 2 inches above theuppermost faceguard bar 52 a and the frontal openingupper edge 11 d. Preferably, thesecond sidewall segment 62 b is reduced along the raisedlateral ridge 62, whereby a peripheral segment of the raisedlateral ridge 62 is substantially flush with theouter shell surface 18. Most preferably, the raisedlateral ridge 62 is flush with theouter shell surface 18 at a point that is rearward of thedynamic connector 16, substantially aligned with the upperchin strap connector 45 a, and/or substantially aligned with the angledfrontal ridge 12 b of theear opening 12 a. As shown inFIG. 13 , therear openings 32 e are positioned in the rear 20 of theshell 11 and between arear edge 22 and a raisedlateral ridge chord 34 that extends: (i) betweenuppermost points 63 of the raisedlateral ridges 62, and (ii) around the rear 20 of theshell 11. As shown inFIGS. 1B, 3, 6 and 11 , a first set of ventilation openings, or air vents, 32 a-c, are arranged along thesidewall 60 a of theband 60. Although only the left half of thehelmet 10 is shown inFIGS. 3 and 11 , thehelmet 10 is symmetric and it is understood that the structures and features shown on the left half, including openings 32 a-c along the right sidewall of theband 60, are also present on the right half (not shown) of thehelmet 10. Preferably, theopenings helmet 10 are collinear with each other, and the openings in the second set (on the right half of the helmet 10) are also collinear with each other. Because theband 60 has a rearward taper, the distance betweenopposed openings band 60, decreases. The initialfrontal opening 32 a is adjacent to an inner shoulder of the raisedlateral ridge 62 and theband 60. Specifically, as shown inFIGS. 1, 1A, 1B, 2, 2A, 3, 6, 6A, 7, 8 , and 11-13, the frontal vent opening 32 a is positioned substantially adjacent to the raisedcentral band 60 and the raisedlateral ridge 62. Preferably, as shown in these figures, the frontal vent opening 32 a is located adjacent to a base portion of thesidewall 60 a and thefirst sidewall segment 62 a, as thesesidewalls outer surface 19 of theshell 11. - Referring to
FIGS. 3, 6 and 17 , theshell 11 further includes a raisedrear band 64 that extends from thecrown 19 rearward to therear shell portion 20. The raisedrear band 64 has a width that remains substantially constant as theband 64 extends rearward and downward. Therear band 64 also has opposed beveled (or inclined) sidewalls 64 a that increases as theband 64 extends rearward. An initial segment of theband 64 commences forward of therearmost opening 32 c and is substantially flush with theshell 11. A pair of opposed rearbeveled ridges 68 extend outward and downward from a rear segment of theband 64. The rearbeveled ridges 68 have sidewalls 68 a that decrease along their length whereby theridges 68 gradually blend into theshell 11. Aventilation opening 32 d resides adjacent aninner shoulder 68 b between theridges 68 and theband 64. Preferably, theventilation opening 32 d has a triangular configuration. Therear band 64 terminates proximate a substantiallyhorizontal ledge 70 that extends between theside regions 24 of thehelmet 10. The substantiallyhorizontal ledge 70 includes anangled surface 72 extending between therear band 64 and theouter shell surface 18. Below theledge 70, therear shell portion 20 includes a pair of recessedregions 74 in an opposed positional relationship. The recessedregion 74 is defined by an arrangement ofangled walls 74 a that form a generally U-shaped configuration. Arear opening 32 e resides within the recessedregion 74 and is positioned adjacent to a frontal or leadingwall 74 b of theangled walls 74 a and between an upper transverse wall 74 c and a lowertransverse wall 74 d. Therear opening 32 e has an elongated configuration with a major axis that is substantially vertical when thehelmet 10 is positioned on the wearer's head. Further, therear opening 32 e has an upper width that exceeds a lower width. As shown inFIGS. 3 and 11 , therear openings 32 c are positioned in the rear 20 of theshell 11 and below afirst chord 31 that extends: (i) between theforward-most points 29 of theear openings 12 a and (ii) around the rear 20 of theshell 11. As shown inFIG. 12 , theshell 11 is configured such that the distance between thesidewall 60 a of the raisedcentral band 60 is less than the distance between the outer edges of therear openings 32 e. - With reference to
FIGS. 3 and 3A , thehelmet 10 includes achin protector 40 that engages thechin 529 ofwearer 500 and couples with theshell 11 in order to secure thehelmet 10 on the wearer's head. Thechin protector 40 includes a centralprotective member 42 that engages the wearer'schin 529 and at least two flexible members or straps 43, 44 extending from thecentral member 42. In use, the upperflexible member 43 engages with anupper connector 45 a extending outward from theshell 11 above anear opening 12 a in theear flap 12 and preferably rearward of thefaceguard connector 16. Similarly, the lowerflexible member 44 engages with alower connector 45 b extending outward from theshell 11 below theear opening 12 a. A frontal portion of theear opening 12 a is defined by an angledfrontal ridge 12 b with abeveled side wall 12 c (seeFIG. 3A ). An upper recessed channel 46 extends rearward from an interiorfrontal edge 11 b of the shellfrontal opening 11 a and along the upper periphery of thejaw flap 13. The upper recessed channel 46 is adjacent an upperbeveled surface 13 a of the jaw flap 13 (seeFIG. 3A ), and theupper connector 45 a is aligned with the upper recessed channel 46. A peripheral downwardly extending transverse bar 52 g is cooperatively dimensioned with the upper channel 46 such that an upperflexible member 43 of thechin protector 40 is positioned between the transverse bar 52 g and the upper channel 46. A lower recessedchannel 48 extends from thelower edge 22 of theshell 11 upward and rearward along the lower periphery of thejaw flap 13. The lower recessedchannel 48 is adjacent a lower beveled surface 13 b of thejaw flap 13, and thelower connector 45 b is aligned with the lower recessedchannel 48. Due to the recessed nature of the upper andlower channels 46, 48, thejaw flap 13 defines an outermostjaw flap surface 13 c of theshell 11 in the side region of thehelmet 10. Theshell 11 also includes anotch 47 formed in the loweredge shell surface 22 and below theear opening 12 a, and preferably, thenotch 47 is aligned with thelower channel 48. Preferably, notch 47 has at least oneangled segment 47 a and potentially a plurality ofangled segments 47 a, b that result in a generally V-shaped configuration; however, other shapes of notches, if desired, could be utilized. - Each
flexible member coupler 49 with a female snap connector that engages with the male upper andlower connectors 45 a, b, respectively, to define a secured position. When thechin protector 40 is in a secured position and thehelmet 10 is on the wearer's head 500 (seeFIG. 3 ), the upper channel 46 receives anextent 43 a of the upperflexible member 43 and thelower channel 48 receives anextent 44 a of the lowerflexible member 44. Thus, in the secured position, the upper and lowerflexible members lower channels 46, 48, respectively. In addition, asecond extent 44 b of the lowerflexible member 44 passes throughnotch 47 which improves stability of the lowerflexible member 44 while minimizing undesired movement of themember 44. In general, if a helmet is subjected to a downward impact force upon the face mask, the helmet tends to roll forwardly about a virtual pivot point located slightly above the ear openings.Notch 47 assists in resisting the undesired rolling effect by redirecting the lower flexible member's 44 line of action to a location farther away from the virtual pivot point. In addition, the securement configuration resulting from thechannels 46, 48 and thenotch 47 provide an improvement over the conventional 4 point hookup, or a “high hookup,” of the chin protector because of improved stability of thehelmet 10 on the wearer's head during play. Thus, the retention and proper positioning of thehelmet 10 upon impact(s) is improved. - Referring to
FIGS. 1, 1A, 1B, 2, 2A, 3, 3A, 4A -C, and 6-11, thehelmet 10 features an energy attenuatingfaceguard mounting system 14, including thefaceguard 35 and means for dynamically connecting thefaceguard 35, which interact to reduce impact forces received on thefaceguard 35 and transmitted to thehelmet shell 11. Unlike conventional sports helmets andfaceguard connectors 15, the energy attenuatingfaceguard mounting system 14 does not include a connection point with afront bumper 202 at thebrow region 11 c of theshell 11 for thefaceguard 35. In other words and as shown inFIGS. 1, 1A, 1B, 2, 2A, 3, 3A, 4A -C, and 6-11, thehelmet 10 lacks a component that is connected between the front region of the shell and the faceguard. In one embodiment, the dynamic faceguard connecting means comprises a helmet shell connection segment that is movable relative to the remainingshell 11 and that receives a coupler for securement of thefaceguard 35. The helmet shell connection segment can be integrally formed within theshell 11, for example in theear flap 12. Alternatively, the helmet shell connection segment can be formed separately and then operatively joined to theshell 11. For example, theshell 11 can include a generally circular opening that receives and operatively connects with the helmet shell connection segment. The helmet shell connection segment can function similar to a butterfly valve where the connection segment includes a disc that is secured to theshell 11 by a rod and aperipheral region 38 of thefaceguard 35 is secured to the rod either directly or via an actuator. When an impact force is applied to thefaceguard 35, a portion of the connection segment, for example the disc, moves or rotates relative to the remainingshell 11 which allows for movement of theperipheral faceguard region 38. Alternatively, the helmet shell connection segment can flex inward and/or outward when the impact force is applied to thefaceguard 35. In another embodiment, the dynamic faceguard connecting means comprises a plunger assembly coupled to thehelmet shell 11 wherein a first plunger component moves relative to the shell 11 (e.g., substantially normal to the shell 11) when an impact force is applied to thefaceguard 35. The movement of the plunger assembly facilitates movement of thefaceguard 35, including aperipheral faceguard region 38, when the impact force is received by thefaceguard 35. In another embodiment, the dynamic faceguard connecting means comprises thedynamic faceguard connector 16. Referring toFIGS. 1-3A and as explained below, thehelmet 10 includes twodynamic connectors 16, one on eachside region 24 ofshell 11 positioned slightly above theear opening 12 a. Thehelmet 10 also includes a pair of lower (non-dynamic)connector 15 positioned on thejaw flap 13 near thelower shell edge 22. Alternatively, thehelmet 10 may include a greater number ofdynamic connectors 16, for example, fourdynamic connectors 16 wherein thehelmet 10 has a pair of upperdynamic connectors 16 and a pair of lowerdynamic connectors 16. - The
faceguard 35 comprises a plurality ofelongated bar members 39, which may be formed of any suitable material having the requisite strength and durability characteristics to function as a football helmet faceguard. Themembers 39 may be preferably formed of a metallic material, such as steel or titanium, and as is known in the art, thebar members 39 may be provided with a durable coating (e.g., plastic coating). Additionally, thebar members 39 may be of a solid or tubular cross-sectional configuration. Alternatively,bar members 39 may be formed of a suitable plastic material, including a fiber reinforced plastic resin, having the requisite strength and durability characteristics to perform the functions of a football helmet faceguard. Thefaceguard connectors bar members 39 of thefaceguard 35. Thefaceguard connectors quick release coupler 50, which is described in more detail in pending U.S. patent application Ser. No. 12/082,920, which is incorporated herein by reference. Alternatively, an elongated fastener, such as a threaded screw, may be employed with thefaceguard connectors faceguard 35 to thehelmet 10. - Referring to at least
FIGS. 1, 1B, 3 and 3A , a pair ofdynamic faceguard connectors 16 and thequick release coupler 50 connect an upper portion of thefaceguard 35 to aninterface area 11 e of theshell 11 at theear flap 12 and over a superior (or frontal) portion of the helmet wearer's temporal lobe. As shown inFIGS. 1B, 12 and 13 , theinterface area 11 e is outwardly raised or offset relative to the adjacent portion of theshell 11. Also, as shown in these figures, opposed ends of the thickenedsegment 11 g adjoin theinterface areas 11 e to provide a continuous, uninterrupted frontal offset of theshell 11. Theinterface area 11 e has significant dimensions such that it extends from the interiorfrontal edge 11 b rearward past a shell opening 200 (that receives an extent of the coupler 50). Focusing onFIG. 3A , a rear edge of theinterface area 11 e is positioned rearward of thefaceguard 35, theupper faceguard connector 16, and thelower faceguard connector 15. Preferably, thefaceguard connector 16 is positioned adjacent theinterior edge 11 b of the frontal shell opening 11 a and below anupper edge 11 d of thefrontal opening 11 a. More preferably, thefaceguard connector 16 is positioned above theear opening 12 a and thejaw flap 13. Thedynamic faceguard connectors 16 define an uppermost faceguard securement point located over the helmet wearer's superior temporal lobe and lateral to thebrow region 11 c of theshell 11. The uppermost faceguard securement point is also below the frontal openingupper edge 11 d and upper substantiallyhorizontal bar 52 a of thefaceguard 35, and above theear opening 12 a andjaw flap 13. At least one horizontalupper bar 52 a of thefaceguard 35 extends between thedynamic faceguard connectors 16 and the opposed faceguard securement points provided by thedynamic connectors 16. A second substantially horizontalupper bar 52 b is proximate and below theupper bar 52 a and extends between transverseintermediate bars 52 f. Alternatively the transverseintermediate bars 52 f are omitted and the secondupper bar 52 b is joined with the firstupper bar 52 a. Both of theupper bars 52 a, b are offset from theshell 11 and do not contact thebrow region 11 c (or front region) of theshell 11. In other words, theupper bars 52 a, b extend between theconnectors 16 and along thebrow region 11 c without connecting to thebrow region 11 c. Thus, at least theuppermost bar 52 a spansfrontal opening 11 a and the distance between thedynamic connectors 16 without connecting to the nameplate (or front bumper) 202 affixed to thebrow region 11 c. Accordingly, the brow (front)region 11 c of theshell 11 lacks a faceguard connector. The upper bars 52 a, b have a length with a curvilinear configuration that substantially corresponds to the curvilinear configuration of thebrow region 11 c of theshell 11. The offset between theupper bars 52 a, b, and theshell 11 forms a gap G or standoff (seeFIGS. 5, 6 and 6A ) that is generally greater than 0.25 inch, and preferably between 0.25 inch and 0.5 inch. Unlike the present invention, conventional helmets include a faceguard that is secured to the helmet by at least one connector, typically a pair of connectors, coupled to the helmet's brow region whereby at least one upper bar, typically two upper bars contact the brow region. Conventional faceguards are further secured by at least one additional pair of connectors, each being coupled to an earflap of the shell. - Referring to
FIGS. 9, 9A and 10 , thedynamic connector 16 includes thequick release coupler 50 that extends through agrommet 90 positioned within ashell opening 200. Thecoupler 50 is received by afastening washer 91 that extends through both thegrommet 90 and theshell opening 200. As explained in pending U.S. patent application Ser. No. 12/082,920, which is incorporated by reference, thequick release coupler 50 also comprisessleeve body 92, an actuator orpin 93, and aspring 94. Thesleeve body 92 receives theactuator 93 to removably secure thedynamic connector 16 to theshell 11. As briefly explained above, the quickrelease coupler mechanism 50 is employed to secure thedynamic faceguard connectors 16 to theshell 11. Thecoupler mechanism 50 that provides for rapid attachment and detachment of theconnectors 16 and thefaceguard 35 from theshell 11 without the deliberate and time-consuming use of a screwdriver (or cutting tool for removal). Thereleasable coupler mechanism 50 extends through theopening 120 in thebracket 100 and into ashell opening 200. Thecoupler mechanism 50 further includes a head, a washer, ball, and a retaining notch. Thecoupler 50 is retained in a use position (seeFIG. 9 ) by the engagement between the ball, the retaining notch and the distal end segment of the pin. To move thecoupler 50 the use position through an intermediate position to a disconnected position, an inwardly directed actuation force is applied to the pin by an object. Once these internal coupler components are disconnected, thebracket 100 can be removed to allow for removal of thefaceguard 35 to arrive at the disconnected position. - As shown in
FIGS. 3A, 4A -C, thedynamic faceguard connector 16 comprises abracket 100 with a movable segment and a stable segment that are operatively connected to each other to facilitate movement of thefaceguard 35 when an impact force is applied thereto. In the embodiment shown in the Figures, the bracket's movable segment is theperipheral bracket segment 113 and the stable segment is theinternal segment 114. Thebracket 100 also includes a band orstrap member 102 that wraps around aperipheral bar member 52 c that extends downwardly and transversely from theupper bar member 52 a. The lower faceguard connector 15 (discussed in greater detail in pending U.S. patent application Ser. No. 12/082,920) also comprises abracket 15 a with a band that encircles the periphery of aperipheral member bar 52 d that extends upwardly and transversely from alower bar member 52 e. Theband 102 ofbracket 100 forms areceiver 104 that encircles thebar 52 c, wherein thereceiver 104 provides a single encircling point for thefaceguard bar 52 c. Thereceiver 104 is oriented substantially perpendicular to the longitudinal axis of thebracket 100. Thebracket 100 additionally includes arear flange 106 that includes theband 102 and thereceiver 104, and afrontal tab 108. As shown inFIG. 4A , theflange 106 also includes anindentation 106 a located approximately at a mid-point of the width of theflange 106. Afirst side rail 110 and asecond side rail 112 extend between theflange 106 and thefrontal tab 108. Theflange 106, thefrontal tab 108, and the side rails 110, 112 collectively comprise theperipheral segment 113 of thebracket 100. Thebracket 100 has a “clam-shell” design such that it opens about thereceiver 104 andflange 106 to receive thefaceguard bar 52 c. Due to the clam-shell configuration, thebracket 100 has an outer half orportion 122 and aninner portion 124, as described in more detail below, that meet at a rear seam extending along thereceiver 104. Thus, theperipheral segment 113 of theouter portion 122 includes an outerside rail segment 110 a of thefirst side rail 110, an outer side rail segment 112 a of thesecond side rail 112, and anouter segment 108 a of thefrontal tab 108. Similarly, theperipheral segment 113 of theinner portion 124 includes an innerside rail segment 110 b of thefirst side rail 110, an inner side rail segment 112 b of thesecond side rail 112, and aninner segment 108 b of thefrontal tab 108. Consequently, thefirst side rail 110 comprises the outerside rail segment 110 a and the innerside rail segment 110 b; thesecond side rail 112 comprises the outer side rail segment 112 a and the inner side rail segment 112 b; and thefrontal tab 108 comprises theouter segment 108 a and theinner segment 108 b. - The
connector bracket 100 includes a hingedinternal segment 114 that enables thebracket 100 to flex when impact forces are applied to thefaceguard 35. As explained below, theperipheral segment 113 flexes or moves relative to theinternal segment 114 when an impact force F is applied to theface guard 35. Because thebracket 100 has a clam-shell configuration, the hingedsegment 114 has anouter portion 114 a associated with theouter portion 122, and aninner portion 114 b associated with theinner portion 124. The hingedinternal segment 114 connects to thefrontal tab 108, and includes afrontal recess 115 at the interface with thefrontal tab 108. Thefrontal recess 115 defines ahinge line 115 a for theinternal segment 114, wherein both are substantially perpendicular to the longitudinal axis of thebracket 100. A rear extent of the hingedinternal segment 114 that is opposite thefrontal recess 115 is free or not connected to thefirst side rail 110 and thesecond side rail 112. - Also, the hinged
internal segment 114 does not connect to theflange 106 and therefore, the hingedinternal segment 114 and theflange 106 move independently of each other. Agap 116 is formed between the hingedinternal segment 114, thefirst side rail 110, thesecond side rail 112, and theperipheral flange 106, namely the internal walls of same. Thegap 116 includes opposed recesses 118 a, 118 b disposed adjacent thefrontal tab 108. The opposed recesses 118 a, 118 b separate the hingedinternal segment 114 from thefirst side rail 110 and thesecond side rail 112, allowing motion of the side rails 110, 112 relative to the hingedinternal segment 114. Thegap 116 has curvilinear segments as shown inFIG. 3A . The curvilinear segments of thegap 116 are complimentary to a profile of a periphery of the hingedinternal segment 114. The hingedinternal segment 114 further comprises an opening or bore 120. Theopening 120 is adapted to receive an elongated fastener, such ascoupler 50, to secure thebracket 100 and thefaceguard 35 to theshell 11. The hingedinternal segment 114 additionally has acountersink 121, aligned with theopening 120, to enable a head portion of the fastener to reside below theouter portion 122. - As shown in
FIGS. 4A-C , 9, 9A, and 10, theouter bracket portion 122, including the outer firstside rail segment 110 a, the outer second side rail segment 112 a, and the frontal tabouter segment 108 a, defines an inclinedouter wall surface 126 of theouter portion 122 that extends between thefront tab 108 and therear flange 106. As shown inFIG. 4C , the inclinedouter wall surface 126 is configured to allow for the inclusion of text, such as a company identifier or logo. Theinner bracket portion 124, including the inner firstside rail segment 110 b, the second outer side rail segment 112 b, and the frontal tabinner segment 108 b, defines a generally planarinner wall surface 128. Referring toFIG. 4B , theinternal portion 114 b of theinner portion 114 has an inner surface 114 d that is slightly recessed from theinner wall surface 128. Preferably, anouter surface 114 c of theouter segment 114 a of theinternal segment 114 is recessed from theouter wall 126 of theouter portion 122 thereby forming an offset K. Further, aninternal cavity 117 is formed between theinternal segment 114 the internal portions of the side rails 110, 112 and theflange 106. Preferably, the offset K varies over the length of thebracket 100, in that the offset K is smaller near thefrontal tab 108 and the offset K is larger near theperipheral flange 106. The offset K facilitates pivotal movement of theperipheral segment 113 relative to theinternal segment 114 upon an impact to thefaceguard 35. In addition, one of theouter portion 122 and theinner portion 124 has aprotrusion 130 that interacts with arecess 132 formed in the other of theouter portion 122 and theinner portion 124, preferably at a location adjacent the hinge line of theinternal segment 114. In the embodiment discussed above, the bracket's movable segment is theperipheral segment 113 and the stable segment is the internal segment that are operatively connected. Alternatively, theperipheral segment 113 is fixed andinternal segment 114 is movable when an impact force is applied to thefaceguard 35, as discussed below. In another alternate configuration, thebracket 100 includes a front segment and a rear segment, wherein one of the segments moves when an impact force is applied to thefaceguard 35 and the other of the segments remains stable and secured to theshell 11. -
FIGS. 6 and 9 show the energy attenuatingfaceguard mounting system 14 in an installed or first position P1 (and prior to any impact to the helmet 10), wherein thefaceguard 35 is dynamically connected to thehelmet 10 by theconnectors 16. The first position P1 reflects theconnector 16 position before an impact is applied to thefaceguard 35, or the post impact state where energy from an impact has been fully absorbed and dissipated by the energy attenuatingfaceguard mounting system 14. In the first position P1,upper bar members 52 a, b extend between theconnectors 16 but do not connect with thehelmet 10 at or near the shell'sbrow region 11 c orfront bumper 202, thereby providing the gap G. Referring toFIG. 9 , theinner wall 128 of theinner portion 124 is spaced a distance D1 from theouter surface 18 of theshell 11 at theinterface area 11 e. The distance D1 also represents the distance between theouter shell surface 18 and the inner first and secondside rail segments 110 b, 112 b. In general terms, when an impact to thefaceguard 35 occurs, theinternal segment 114 remains substantially stable, but theflange 106 and the side rails 110, 112 of theperipheral segment 113 flex relative to theinternal segment 114. Depending upon the magnitude and duration of an impact to thefaceguard 35, this movement occurs in two directions—outward from theshell 11, and inward towards theshell 11—which provides theconnector 16 with dynamic characteristics upon an impact to thefaceguard 35. Thefaceguard 35 is shown in the Figures as single structure formed from a plurality of intersecting bar members. Alternatively, thefaceguard 35 comprises distinct portions, such as an upper portion and a lower portion wherein each portion includes a plurality of intersecting bar members. Thisfaceguard 35 configuration can result from the removal of the lower vertical bar members 39 (seeFIG. 1 ) that extend from the lower portion to the upper portion. Assuming the resulting upper portion of the faceguard is secured to thehelmet shell 11 by thedynamic connectors 16, the upper faceguard portion will behave in a manner consistent with that described below for both on-center and off-center impacts. -
FIGS. 7 and 10 show the energy attenuatingfaceguard mounting system 14 in a second position P2 wherein an “on-center” impact force F, that is substantially lateral, is applied to acenter point 36 of thefaceguard 35. The on-center impact F occurs within thirty degrees) (30°) of thefaceguard center point 36, which may be defined by a substantially vertical center bar member 37. Alternatively, the center bar member 37 is omitted and thecenter point 36 is located between two other vertical bar members, for example vertical bars in the upper or lower portion of thefaceguard 35. When the on-center impact F occurs, thefaceguard 35 is displaced towards theshell 11 whereby thebracket 100 flexes outward relative to (or away from) theouter shell surface 18 at theinterface area 11 e. Specifically, theperipheral flange 106, thefirst side rail 110 and thesecond side rail 112 move away from theouter shell surface 18 at theinterface area 11 e, while theinternal segment 114 remains stable due to the securement with thehelmet shell 11 provided by thecoupler 50. Thus, theperipheral flange 106, thefirst side rail 110 and thesecond side rail 112 move relative to theinternal segment 114 along thehinge line 115 a. Referring toFIG. 10 , a distance D2 (where D2 exceeds D1) exists between theouter shell surface 18 and theinner wall 128 of theinner portion 124. The distance D2 also represents the distance between theouter shell surface 18 and the inner first and secondside rail segments 110 b, 112 b. By referencingFIG. 10 for bothconnectors 16,FIG. 7 indicates that bothfaceguard connectors 16 will behave similarly and experience the same amount of flex during an on-center impact. However, it is understood that an impact force F that is not purely on-center but that falls within 30 degrees of on-center (or within the total 60 degree window) may cause oneconnector 16 to behave slightly differently than asecond connector 16. For example and referring toFIG. 7 , an impact force that is applied 10 degrees off-center on a center left portion of theface guard 35 will cause the helmet'sleft connector 16 a to flex less than the helmet'sright connector 16 b. Therefore, the distance D2 between theleft connector 16 a and theouter shell surface 18 at theinterface area 11 e is less than the distance D2 between theright connector 16 b and theouter shell surface 18 at theinterface area 11 e. - The movement of the
faceguard 35 provided by thedynamic connectors 16 dissipates energy received by thefaceguard 35 from the on-center impact, and temporarily reduces the gap G between the faceguard upper bars 52 and the shell 11 (as compared to the gap G in the first position P1 ofFIG. 6 ). Under most impact conditions, the gap G is temporarily reduced but not entirely eliminated, whereby the transmission of faceguard impact forces to theshell front 21 is reduced. Due to the nature of the faceguard impact, thedynamic faceguard connector 16 experiences both inward and outward movement relative to theshell 11 during an on-center impact. The extent of this dual movement varies with a number of impact factors, including the speed of the impact, the duration of the impact and the faceguard location of the impact. Nonetheless, under a moderate or severe on-center impact, theconnector bracket 100 rapidly moves (or flexes) outward relative to theshell 11 and then inward relative to theshell 11 several times per impact. In this regard, the connector'sflange 106 andside rails internal segment 114 until the impact energy is sufficiently dissipated. To further aid energy attenuation, thebar members 39 of thefaceguard 35, including the uppermost bars 52 a, b elastically deform upon an impact. During a significant on-center impact force F, thefaceguard 35 elastically deforms such that the opposedperipheral faceguard regions 38 move outward or away from thehelmet shell 11. Thus, thedynamic faceguard connectors 16 a, b facilitate and/or enable movement of theperipheral faceguard regions 38 that is substantially normal or substantially perpendicular to theouter shell surface 18 at theinterface area 11 e when an on-center impact force F is applied to thefaceguard 35. -
FIGS. 8, 9A, and 10 show the energy attenuatingfaceguard mounting system 14 in a third position P3 wherein an “off-center” impact force F, that is substantially lateral, is applied to thefaceguard 35. The off-center impact F occurs to the side of theface guard 35 beyond thirty degrees (30°) of thefaceguard center point 36. Referring toFIG. 8 , the off-center impact F occurs at a left portion of thefaceguard 35, between alowermost bar 52 e and theuppermost bar 52 a. Due to the off-center impact force F, the gap G on the left side of theface guard 35 is temporarily eliminated. The gap G on the right side of theface guard 35 is similar to that for the first position P1 (seeFIG. 6 ), however, under certain impact conditions, this gap G may slightly, temporarily increase. When the off-center impact F occurs, theleft faceguard connector 16 a and the left peripheral faceguard portion 38 a compresses towards theinterface area 11 e of thehelmet shell 11, and theright faceguard connector 16 b and the right peripheral faceguard portion 38 b flexes away from theinterface area 11 e of thehelmet shell 11. Thus, thefaceguard connector 16 and theperipheral faceguard portion 38 located on an opposite side of the faceguard as the off-center impact force F initially moves outward and substantially normal relative to theinterface area 11 e of theshell 11 while thefaceguard connector 16 and theperipheral faceguard portion 38 on the same side as the impact force F initially moves inward and substantially normal relative to the interface areal le of theshell 11. Upon an off-center impact, thefaceguard connectors 16 behave differently which demonstrates the dynamic nature of theconnector 16. When the off-center impact F occurs, theright connector 16 b, including thebracket 100, behaves in the manner described above and shown inFIG. 10 . Thebracket 100 of theleft connector 16 a initially moves towards theinterface area 11 e of thehelmet shell 11 and depending upon the magnitude and duration of the impact F, theinner bracket wall 128 makes contact with theouter shell surface 18. In this manner, the distance D3 between theouter shell surface 18 and theinner wall 128 of theinner portion 124 is temporarily eliminated. Thebracket 100 of theleft connector 16 a then moves away from the shellouter surface 18. When the off-center impact force F has a lesser magnitude and/or duration, theinner portion 124 of theconnector 16 a may not contact theouter shell surface 18 and the distance D3 is less than D2 or D1. Thus, thefaceguard connector 16 on the same side of thefaceguard 35 as the off-center impact F initially moves towards thehelmet shell 11, and theconnector 16 on the other side of thefaceguard 35 initially moves away from thehelmet shell 11. - While substantially lateral or horizontal impact forces F are discussed above, it has also been observed that an on-center impact force F applied in a vertically downward direction to the
faceguard 35 cause thedynamic faceguard connectors 16 to flex outward relative to theshell 11. This behavior is similar to when a lateral impact force F is applied on-center to thefaceguard 35. Conversely, an on-center impact force F applied in a vertically upward direction (towards the crown 19) to thefaceguard 35 cause thedynamic faceguard connectors 16 to flex inward relative to theshell 11. Testing theinventive helmet 10 involved mounting it on a Hybrid III headform that is coupled to a test table that is movable along a single axis. A ram is moved axially along the single axis in the same direction that the moveable table may travel. The ram was moved at different speeds, such as, for example, 5 mis, 7 mis, and/or 9 mis, to deliver a force to thefaceguard 35 of thehelmet 10. Sensors within the headform measure lateral acceleration as well as severity index of the impact of the ram with thehelmet 10. This testing has shown that thehelmet 10 and its energy attenuatingfacemask mounting system 14 significantly reduces both lateral acceleration and severity index of impacts delivered by the ram to thefaceguard 35 over a variety of impact speeds. -
FIGS. 5A and 5B show a front bumper ornameplate 202 affixed to thebrow region 11 c of theshell 11 by internal fasteners that are not externally visible. Thebumper 202 has a curvilinear configuration that substantially corresponds to the configuration of thebrow region 11 c, and facilitates the positioning and securement of theinternal padding assembly 300.Fasteners 204 a, 204 b pass through openings 11 f in theshell 11 andbumper opening 215 and are received byrespective nuts 206 a, 206 b that are secured within aninternal pocket 205 formed in thebumper 202. Thefastener 204 a, 204 b extends through only a portion of thebumper 202 and no fastener extends through the entirety of thebumper 202. Preferably, thepockets 205 are in an opposed relationship, wherein eachpocket 205 has anaccess slot 207 aligned with the periphery of thebumper 202, such as asidewall 202 a or atop wall 202 b. As shown inFIG. 5A , theslot 207 is formed in thesidewall 202 a of thebumper 202 and leads to thepocket 205 and thebumper opening 215, which are both positioned a distance from thesidewall 202 a. Theinternal pocket 205 retains thenuts 206 a, 206 b as thehelmet 10 lacks any connectors for the upper bar 52 of thefaceguard 35 at thebrow region 11 c of theshell 11. Thebumper 202 also includes alower groove 203 that is defined by aninternal flange 208 and that engages the frontal openingupper edge 11 d of theshell 11 to facilitate engagement thereto. As shown inFIGS. 5A and 5B , a firstinner wall 202 c and a secondinner wall 202 d of thebumper 202 resides adjacent theouter surface 18 of theshell 11 and theflange 208 is positioned between the frontal openingupper edge 11 d and afront pad 302 of theinternal pad assembly 300. Thebumper 202 contains an outer surface or panel that allows for indicia, such as the manufacturer of thehelmet 10, or the name of a team of thewearer 500. Because the nuts 206 a, 206 b are internally retained within thepocket 205 and there is no faceguard connection point at thebrow region 11 c, thehelmet 10 lacks any externally visible fastener hardware at thebrow region 11 c. In contrast, conventional helmets utilize external fastening hardware to secure the faceguard to the bumper and helmet, which reduces the aesthetic appearance of the conventional helmet. -
FIGS. 11-16 show theshell 11 having a transition region TR, where the thickness of theshell 11 varies from a first thickness at thefront portion 21 of theshell 11 to therear portion 20 of theshell 11. In the embodiment shown, the transition region TR is a transverse band that extends between the symmetric left andright side regions 24 a,b of theshell 11, preferably rearward of theear openings 12. Preferably, the transition region extends from thelower shell edge 22 of the left shell portion 22 a to thelower shell edge 22 of the right shell portion 22 b. The transition region TR intersects and includes the raisedcentral band 60 that extends from thefront shell portion 21 and along thecrown 19. The transition region TR is roughly 1 inch wide and the thickness of theshell 11 transitions from about 0.125 inches in thefront shell portion 21 to about 0.100 inches in therear shell portion 20. This reduction in width reduces the weight of thehelmet 10, and the amount of raw material used to form theshell 11.FIG. 12 provides a frontal view of thehelmet 10, with a central axis A-A dividing theshell 11 into theleft region 24 a and right region 24 b. Theshell 11 includes an internal rib extending along theinner shell surface 17 from therear shell portion 20 upward through thecrown 19 and towards thefront shell portion 21. Section plane 13-13, corresponding to the cross-section ofFIG. 13 , is taken slightly right of the central axis A-A (as viewed in the Fig.) and beyond the internal rib on the left shell portion 22 a. Referring toFIGS. 14 , theshell 11 has a frontal shell segment with a first thickness T1 forward of the transition region TR and a rear shell segment with a second thickness T2 rearward of the transition region TR, wherein the first thickness T1 exceeds the second thickness T2. - Referring to the schematic views of
FIGS. 15 and 16 , the transition region TR extends between the two thicknesses T1, T2. The first thickness T1 is defined between an innerfrontal shell surface 17 a and theouter shell surface 18, while the second thickness T2 is defined between an innerrear shell surface 17 b and theouter shell surface 18. The innerfrontal shell surface 17 a has a first radius ofcurvature 212 and atangential arrow 212 a thereof, as well as a second radius ofcurvature 214 and a tangential arrow 214 a thereof. To provide a substantially smooth configuration to theinner shell surface 17 that avoids abrupt or sharp changes to the shell geometry, it is preferable that the transition region TR has a radius of curvature 216 (seeFIG. 16 ) that is tangential to both thefrontal shell surface 17 a and therear shell surface 17 b proximate thearrows 212 a, 214 a, respectively - 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 (20)
1. A football helmet comprising:
a shell configured to receive a head of a wearer of the helmet, the shell having a front region, a rear region, left side region and right side region, wherein each side region has an ear opening;
a faceguard assembly including:
a faceguard comprising a plurality of bar members including an upper horizontal bar member extending across the front region of the shell without contacting said front region,
a upper left connector bracket that secures a peripheral bar member of the faceguard to the shell, the upper left connector bracket having a clamshell configuration with a rear segment and a front segment, wherein said front segment includes an upper left opening that receives a upper left elongated coupler to couple the upper left connector bracket and the faceguard to the left side region,
a lower left connector bracket that secures a peripheral bar member of the faceguard to the shell, the lower left connector bracket having a clamshell configuration with a rear segment and a front segment, wherein said front segment includes an lower left opening that receives a upper left elongated coupler to couple the lower left connector bracket and the faceguard to the left side region,
a upper right connector bracket that secures a peripheral bar member of the faceguard to the shell, the upper right connector bracket having a clamshell configuration with a rear segment and a front segment, wherein said front segment includes an upper right opening that receives a upper right elongated coupler to couple the upper right connector bracket and the faceguard to the right side region,
a lower right connector bracket that secures a peripheral bar member of the faceguard to the shell, the lower right connector bracket having a clamshell configuration with a rear segment and a front segment, wherein said front segment includes an lower right opening that receives a lower right elongated coupler to couple the lower right connector bracket and the faceguard to the right side region,
wherein a continuous gap is formed between the upper horizontal bar member of the faceguard and the front region of the shell prior to an impact force being applied to the faceguard,
wherein the continuous gap extends along the length of the upper horizontal bar member and the front shell region, the helmet lacking a component that is coupled to both the front shell region and the faceguard, and
wherein, when the helmet is worn by a wearer, each of the upper left, upper right, lower left, and lower right elongated couplers are positioned forward of the ear openings.
2. The football helmet of claim 1 , wherein both the upper left and upper right connector bracket have a hinge that operably joins said front and rear segments; and
wherein when an on-center impact force is applied to the faceguard, the front bracket segment remains stable while the rear bracket segment moves substantially normal to an outer surface of the shell to facilitate movement of the upper horizontal bar member towards the front region of the shell.
3. The football helmet of claim 1 , wherein when an on-center impact force is applied to the faceguard, the upper left and upper right connector brackets moves substantially normal to an outer surface of the shell to facilitate movement of the upper horizontal bar member towards the front region of the shell in response to said impact force.
4. The football helmet of claim 1 , wherein, when the faceguard assembly is in an installed position prior to an impact force being applied to the faceguard, the positional arrangement between said upper horizontal bar member of the faceguard and an extent of the front region of the shell provides a continuous gap greater than 0.25 inch.
5. The football helmet of claim 1 , wherein in an installed position prior to an impact force being applied to the faceguard, the rear bracket segment is positioned at a first distance defined between an inner wall of the rear bracket segment and the shell;
wherein upon an impact force being applied to the faceguard, the rear bracket segment being displaced a second distance defined between said inner wall and said shell; and,
wherein the first distance is less than the second distance.
6. The football helmet of claim 1 , wherein the upper horizontal bar member has a curvilinear configuration that corresponds to a curvilinear configuration of a brow region of the front portion of the shell to provide the continuous gap.
7. The football helmet of claim 1 , wherein shell has a front bumper that includes an internal fastener that extends through the shell and is not externally visible, wherein the internal fastener secures the front bumper to the front region of the shell, and
wherein the upper horizontal bar member extends across both: (i) the front region of the shell and (ii) the front bumper without contacting either: (i) the front region of the shell or (ii) the front bumper.
8. The football helmet of claim 1 , wherein the front bumper lacks an external faceguard connector.
9. The football helmet of claim 1 , wherein the front bumper lacks a fastener that extends through the entirety of the front bumper.
10. The football helmet of claim 1 , wherein when an on-center impact force is applied to the faceguard, the upper left and upper right connector brackets flex outward relative to the shell and the upper horizontal bar member moves towards the front bumper in response to said impact force.
11. The football helmet of claim 1 , wherein the front bumper includes an internal pocket that has an access slot designed to allow for the insertion of a nut, and wherein a portion of the internal fastener extends into the nut and resides within the internal pocket.
12. The football helmet of claim 1 , wherein each side region includes a lower recessed channel extending upward and rearward from a lower edge of the shell, and wherein the lower recessed channel is configured to receive an extent of a lower elongated strap member that extends outwardly from the central protective member.
13. A football helmet comprising:
a shell configured to receive a head of a wearer of the helmet, the shell having:
a front region,
a rear region,
a first side region having a first interface area with an outer surface, said outer surface of the first interface area is offset from an outer surface of the shell that is adjacent to the first interface area, and
a second side region having a second interface area with an outer surface, said outer surface of the second interface area is offset from an outer surface of the shell that is adjacent to the second interface area;
a faceguard assembly including:
a faceguard including opposed peripheral bar members including an upper horizontal bar member extending across the front region of the shell without contacting said front region;
a pair of connector brackets for securing the faceguard to the shell, a first connector bracket securing a first peripheral bar member to a first interface area of the shell and a second connector bracket securing a second peripheral bar member to a second interface area of the shell, the first and second connector brackets each having a clamshell configuration with a rear segment and a front segment, wherein said front segment includes an opening that receives an elongated coupler to couple the bracket and the faceguard to a respective first or second interface area of the shell;
wherein a continuous gap is formed between the upper horizontal bar member of the faceguard and the front region of the shell prior to an impact force being applied to the faceguard,
wherein the continuous gap extends along the length of the upper horizontal bar member and the front shell region, whereby the helmet lacks a component that connects the faceguard to the front region of the shell.
14. The football helmet of claim 13 , wherein when an on-center impact force is applied to the faceguard, the front bracket segment remains stable while the rear bracket segment moves substantially normal to the respective interface area of the shell to facilitate movement of the upper horizontal bar member towards the front region of the shell.
15. The football helmet of claim 14 , wherein when an off-center impact force is applied off-center to the faceguard, the first connector bracket moves differently than the second connector bracket, wherein the rear segment of the first connector bracket moves towards the first interface area of the shell and the rear segment of the second connector bracket moves substantially normal to the second interface area of the shell.
16. The football helmet of claim 13 , wherein the continuous gap extends beyond the front region of the shell and into ear flap regions of the shell.
17. The football helmet of claim 13 , wherein the first interface area is located within a first ear flap region of the shell and the second interface area is located within a second and opposing ear flap region of the shell.
18. The football helmet of claim 13 , wherein, when the faceguard assembly is in an installed position prior to an impact force being applied to the faceguard, the positional arrangement between said upper horizontal bar member of the faceguard and said front bumper provides a continuous gap that is between 0.25 and 0.50 inch.
19. The football helmet of claim 13 , wherein in an installed position prior to an impact force being applied to the faceguard, the rear bracket segment is positioned at a first distance defined between an inner wall of the rear bracket segment and the shell;
wherein upon an impact force being applied to the faceguard, the rear bracket segment is displaced a second distance defined between said inner wall and said shell; and,
wherein the first distance is less than the second distance.
20. The football helmet of claim 13 , wherein the upper horizontal bar member has a curvilinear configuration that corresponds to a curvilinear configuration of a brow region of the front portion of the shell to provide the continuous gap.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US17/523,689 US20220061448A1 (en) | 2010-04-30 | 2021-11-10 | Protective sports helmet |
Applications Claiming Priority (4)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US34356710P | 2010-04-30 | 2010-04-30 | |
US13/068,104 US9289024B2 (en) | 2007-04-16 | 2011-05-02 | Protective sports helmet |
US15/076,106 US20160199720A1 (en) | 2007-04-16 | 2016-03-21 | Protective sports helmet |
US17/523,689 US20220061448A1 (en) | 2010-04-30 | 2021-11-10 | Protective sports helmet |
Related Parent Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US15/076,106 Continuation US20160199720A1 (en) | 2007-04-16 | 2016-03-21 | Protective sports helmet |
Publications (1)
Publication Number | Publication Date |
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US20220061448A1 true US20220061448A1 (en) | 2022-03-03 |
Family
ID=80355902
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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US17/523,689 Abandoned US20220061448A1 (en) | 2010-04-30 | 2021-11-10 | Protective sports helmet |
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US (1) | US20220061448A1 (en) |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
USD958464S1 (en) * | 2019-01-04 | 2022-07-19 | Vicis Ip, Llc | Athletic helmet facemask |
US20220354204A1 (en) * | 2021-05-06 | 2022-11-10 | Clearview Systems, Llc | Protective sports face mask |
USD980537S1 (en) * | 2014-02-12 | 2023-03-07 | Riddell, Inc. | Football helmet |
US11918070B2 (en) | 2020-01-03 | 2024-03-05 | Vicis Ip, Llc | Facemask system |
-
2021
- 2021-11-10 US US17/523,689 patent/US20220061448A1/en not_active Abandoned
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
USD980537S1 (en) * | 2014-02-12 | 2023-03-07 | Riddell, Inc. | Football helmet |
USD958464S1 (en) * | 2019-01-04 | 2022-07-19 | Vicis Ip, Llc | Athletic helmet facemask |
US11918070B2 (en) | 2020-01-03 | 2024-03-05 | Vicis Ip, Llc | Facemask system |
US20220354204A1 (en) * | 2021-05-06 | 2022-11-10 | Clearview Systems, Llc | Protective sports face mask |
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