US20080256686A1 - Air Venting, Impact-Absorbing Compressible Members - Google Patents
Air Venting, Impact-Absorbing Compressible Members Download PDFInfo
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- US20080256686A1 US20080256686A1 US11/815,486 US81548606A US2008256686A1 US 20080256686 A1 US20080256686 A1 US 20080256686A1 US 81548606 A US81548606 A US 81548606A US 2008256686 A1 US2008256686 A1 US 2008256686A1
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- impact
- enclosure
- inner chamber
- compressible
- compressible member
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Classifications
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- A—HUMAN NECESSITIES
- A41—WEARING APPAREL
- A41D—OUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
- A41D13/00—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches
- A41D13/015—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches with shock-absorbing means
- A41D13/0155—Professional, industrial or sporting protective garments, e.g. surgeons' gowns or garments protecting against blows or punches with shock-absorbing means having inflatable structure, e.g. non automatic
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16F—SPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
- F16F7/00—Vibration-dampers; Shock-absorbers
- F16F7/12—Vibration-dampers; Shock-absorbers using plastic deformation of members
-
- A—HUMAN NECESSITIES
- A41—WEARING APPAREL
- A41D—OUTERWEAR; PROTECTIVE GARMENTS; ACCESSORIES
- A41D31/00—Materials specially adapted for outerwear
- A41D31/04—Materials specially adapted for outerwear characterised by special function or use
- A41D31/28—Shock absorbing
- A41D31/285—Shock absorbing using layered materials
-
- 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
- A42B3/06—Impact-absorbing shells, e.g. of crash helmets
- A42B3/062—Impact-absorbing shells, e.g. of crash helmets with reinforcing means
- A42B3/065—Corrugated or ribbed shells
-
- 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
- A42B3/10—Linings
- A42B3/12—Cushioning devices
- A42B3/121—Cushioning devices with at least one layer or pad containing a fluid
-
- 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
- A63B71/0054—Features for injury prevention on an apparatus, e.g. shock absorbers
-
- 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
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
- B60R19/00—Wheel guards; Radiator guards, e.g. grilles; Obstruction removers; Fittings damping bouncing force in collisions
- B60R19/02—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects
- B60R19/18—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact
- B60R19/20—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact containing mainly gas or liquid, e.g. inflatable
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
- B60R21/00—Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
- B60R21/02—Occupant safety arrangements or fittings, e.g. crash pads
- B60R21/04—Padded linings for the vehicle interior ; Energy absorbing structures associated with padded or non-padded linings
- B60R21/045—Padded linings for the vehicle interior ; Energy absorbing structures associated with padded or non-padded linings associated with the instrument panel or dashboard
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16F—SPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
- F16F13/00—Units comprising springs of the non-fluid type as well as vibration-dampers, shock-absorbers, or fluid springs
- F16F13/04—Units comprising springs of the non-fluid type as well as vibration-dampers, shock-absorbers, or fluid springs comprising both a plastics spring and a damper, e.g. a friction damper
- F16F13/06—Units comprising springs of the non-fluid type as well as vibration-dampers, shock-absorbers, or fluid springs comprising both a plastics spring and a damper, e.g. a friction damper the damper being a fluid damper, e.g. the plastics spring not forming a part of the wall of the fluid chamber of the damper
- F16F13/08—Units comprising springs of the non-fluid type as well as vibration-dampers, shock-absorbers, or fluid springs comprising both a plastics spring and a damper, e.g. a friction damper the damper being a fluid damper, e.g. the plastics spring not forming a part of the wall of the fluid chamber of the damper the plastics spring forming at least a part of the wall of the fluid chamber of the damper
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16F—SPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
- F16F7/00—Vibration-dampers; Shock-absorbers
- F16F7/12—Vibration-dampers; Shock-absorbers using plastic deformation of members
- F16F7/128—Vibration-dampers; Shock-absorbers using plastic deformation of members characterised by the members, e.g. a flat strap, yielding through stretching, pulling apart
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16F—SPRINGS; SHOCK-ABSORBERS; MEANS FOR DAMPING VIBRATION
- F16F9/00—Springs, vibration-dampers, shock-absorbers, or similarly-constructed movement-dampers using a fluid or the equivalent as damping medium
- F16F9/02—Springs, vibration-dampers, shock-absorbers, or similarly-constructed movement-dampers using a fluid or the equivalent as damping medium using gas only or vacuum
- F16F9/04—Springs, vibration-dampers, shock-absorbers, or similarly-constructed movement-dampers using a fluid or the equivalent as damping medium using gas only or vacuum in a chamber with a flexible wall
- F16F9/0472—Springs, vibration-dampers, shock-absorbers, or similarly-constructed movement-dampers using a fluid or the equivalent as damping medium using gas only or vacuum in a chamber with a flexible wall characterised by comprising a damping device
- F16F9/0481—Springs, vibration-dampers, shock-absorbers, or similarly-constructed movement-dampers using a fluid or the equivalent as damping medium using gas only or vacuum in a chamber with a flexible wall characterised by comprising a damping device provided in an opening to the exterior atmosphere
-
- 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
- A63B71/0054—Features for injury prevention on an apparatus, e.g. shock absorbers
- A63B2071/0063—Shock absorbers
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
- B60R19/00—Wheel guards; Radiator guards, e.g. grilles; Obstruction removers; Fittings damping bouncing force in collisions
- B60R19/02—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects
- B60R19/18—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact
- B60R2019/1893—Bumpers, i.e. impact receiving or absorbing members for protecting vehicles or fending off blows from other vehicles or objects characterised by the cross-section; Means within the bumper to absorb impact comprising a multiplicity of identical adjacent shock-absorbing means
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60R—VEHICLES, VEHICLE FITTINGS, OR VEHICLE PARTS, NOT OTHERWISE PROVIDED FOR
- B60R21/00—Arrangements or fittings on vehicles for protecting or preventing injuries to occupants or pedestrians in case of accidents or other traffic risks
- B60R21/02—Occupant safety arrangements or fittings, e.g. crash pads
- B60R21/04—Padded linings for the vehicle interior ; Energy absorbing structures associated with padded or non-padded linings
- B60R2021/0407—Padded linings for the vehicle interior ; Energy absorbing structures associated with padded or non-padded linings using gas or liquid as energy absorbing means
Definitions
- the invention relates generally to thin-walled, impact-absorbing compressible members. More specifically, the invention relates to an air venting, impact-absorbing compressible member, preferably fabricated from thermoplastic elastomer (TPE) material, that can be used in the construction of a wide variety of shock-absorbing and/or impact protective devices, including, without limitation, protective headgear, protective pads for other parts of the body, protective padding for sports arenas such as hockey rink boards and the like, and impact-absorbing devices for vehicles such as bumpers, dashboards and the like.
- TPE thermoplastic elastomer
- Concussions also called mild traumatic brain injury, are a common, serious problem in sports known to have detrimental effects on people in the short and long term.
- a concussion is a temporary and reversible neurological impairment, with or without loss of consciousness.
- Another definition of a concussion is a traumatically induced alteration of brain function manifested by 1) an alteration of awareness or consciousness, and 2) signs and symptoms commonly associated with post-concussion syndrome, such as persistent headaches, loss of balance, and memory disturbances, to list but a few.
- Some athletes have had their career abbreviated because of concussions, in particular because those who have sustained multiple concussions show a greater proclivity to further concussions and increasingly severe symptoms.
- concussions are prevalent among athletes, the study of concussions is difficult, treatment options are virtually non-existent, and “return-to-play” guidelines are speculative. Accordingly, the best current solution to concussions is prevention and minimization.
- Concussion results from a force being applied to the brain, usually the result of a direct blow to the head, which results in shearing force to the brain tissue, and a subsequent deleterious neurometabolic and neurophysiologic cascade.
- Protective headgear is well known to help protect wearers from head injury by decreasing the magnitude of acceleration (or deceleration) experienced by the wearers.
- Currently marketed helmets primarily address linear forces, but generally do not diminish the rotational forces experienced by the brain.
- Helmets fall generally into two categories: single impact helmets and multiple-impact helmets. Single-impact helmets undergo permanent deformation under impact, whereas multiple-impact helmets are capable of sustaining multiple blows. Applications of single-impact helmets include, for example, bicycling and motorcycling. Participants of contact sports, such as hockey and football, use multiple-impact helmets. Both categories of helmets have similar construction.
- a semi-rigid outer shell distributes the force of impact over a wide area and a compressible foam inner layer reduces the force upon the wearer's head.
- the inner layer of single-impact helmets are typically constructed of fused expanded polystyrene (EPS), a polymer impregnated with a foaming agent.
- EPS fused expanded polystyrene
- a thick inner layer requires a corresponding increase in the size of the outer shell, which increases the size and bulkiness of the helmet.
- Inner layers designed for multiple-impact helmets absorb energy through elastic and viscoelastic deformation. To absorb multiple successive hits, these helmets is need to rebound quickly to return to their original shape. Materials that rebound too quickly, however, permit some of the kinetic energy of the impact to transfer to the wearer's head.
- materials with positive rebound properties also called elastic memory, include foamed polyurethane, expanded polypropylene, expanded polyethylene, and foamed vinylnitrile. Although some of these materials have desirable rebound qualities, an inner layer constructed therefrom must be sufficiently thick to prevent forceful impacts from penetrating its entire thickness. The drawback of a thick foam layer, as noted above, is the resulting bulkiness of the helmet. Moreover, the energy absorbing properties of such materials tend to diminish with increasing temperatures, whereas the positive rebound properties diminish with decreasing temperatures.
- the material properties and densities of foam inner layers in helmets have historically been selected to optimally absorb energy for impacts that are considered severe for the particular sport or activity in which the helmets are to be used. Foams are thus relatively ineffective in absorbing impact energies below the severe level. Industry safety standards currently test and certify helmet designs based on their ability to absorb high energy impacts to ensure that helmets protect wearers against severe head injuries, such as skull fractures. Recent evidence has shown that lower energy impacts result in less severe yet still damaging head injuries, typically concussions. Current laboratory certification tests are pass/fail tests, and are not designed to test for prevention of concussions.
- a foam in a helmet When compressed to the is maximum “ride-down” point, a foam in a helmet is said to have “bottomed out”, and acts essentially as a rigid layer that transfers impact energy with little or no absorption directly to the wearer's head.
- the present invention provides a compressible member whose properties, configuration and construction are optimized to maximize its impact-absorbing capabilities over a wide range of impact energies.
- a compressible member comprises a thin-walled enclosure defining a hollow inner chamber containing a volume of fluid such as air.
- the compressible member has at least one orifice by which fluid can vent from its inner chamber when the member experiences an impact.
- the orifice is sized and positioned so that the compressible member provides a rate sensitive response to impacts, i.e., the member provides relatively low resistance to compression in response to relatively low energy impacts and relatively high resistance to compression in response to relatively high energy impacts.
- More than one orifice may also be provided in the compressible member so that air flows into its inner chamber following an impact at a rate that can be selected by the designer depending on the particular application of the member to be equal to, less than, or greater than the rate at which air flows out of the inner chamber during the impact.
- the thin-walled enclosure of the compressible member is preferably fabricated from blow-molded thermoplastic elastomer material (“TPE”).
- TPE materials are uniquely suited for the fabrication of the impact-absorbing, compressible members of the invention because they can be readily and economically molded and shaped into the desired thin-walled, hollow configuration, and because they maintain their compressibility, stretchability and structural integrity in use after experiencing repeated impacts. Additionally, because they are hollow and air filled, the TPE compressible members of the invention are capable of being compressed to substantially greater degrees than conventional foams of the type currently used in protective headgear, without “bottoming out.” This greater degree of “ride down” makes the TPE compressible members of the invention effective in the absorption of a much wider range of impact energies. Other advantages resulting from the use of TPE materials for the compressible members of the invention, and their higher “ride-down” factors, are discussed in more detail below.
- the compressible members of the invention may be assembled side-by-side in a layer, and combined with one or more layers of other materials, to form multilayer impact-absorbing shells for use in a wide variety of applications.
- a protective shell structure comprises a thin outer shell layer, a compressible middle layer comprised of a plurality of the compressible members of the invention arranged in spaced apart positions, and a thin inner layer.
- the outer layer deflects locally causing the compressible members of the middle layer to compress and vent air from their inner chambers.
- the inner layer is preferably provided with one or more passageways that allow the air vented from the compressible members to pass to the inside of the inner layer.
- the outer shell layer and the inner layer are also preferably secured to the compressible middle layer, but not directly or rigidly to each other. This allows the outer layer to shear or rotate relative to the inner layer and thus take up and absorb tangential components of the impact force.
- Multilayered shell structures which include one or more compressible members of the invention can be configured and used in the construction of a wide variety of impact-absorbing devices. Examples disclosed include helmets, protective body pads, sports arena padding, vehicle bumpers, dashboards and the like.
- FIG. 1A is a diagram illustrating an embodiment of a compressible member of the invention having an enclosure with a bellows-like wall construction and defining a hollow inner chamber for holding a volume of fluid (e.g., air).
- a volume of fluid e.g., air
- FIG. 1B is a diagram of a sequence illustrating simulated effects of a high-energy impact to the compressible member of FIG. 1A .
- FIGS. 1C and 1D are diagrams illustrating the stretching and bending (e.g., shearing) capabilities of the compressible member of FIG. 1A .
- FIG. 1E is a diagram of the compressible member of FIG. 1A following an impact.
- FIG. 1F is a diagram illustrating the expansion of the compressible member of FIG. 1A to its uncompressed condition after impact force is removed.
- FIG. 2 is a diagram of another embodiment of a compressible member of the invention having a generally rectangular shape and configuration.
- FIG. 3 is a diagram of a sequence illustrating simulated effects of an impact on another embodiment of a compressible member of the invention having separate in-flow and outflow orifices for the fluid contained in its inner chamber.
- FIG. 4A is a partial, cross-sectional view of an embodiment of a multilayer shell structure, which includes a layer formed of a plurality of compressible members embodied in accordance with the invention, configured to function as a protective helmet for a wearer's head.
- FIG. 4B is a diagram illustrating the operation of protective shell of FIG. 4A during a direct impact.
- FIG. 4C is a diagram illustrating the operation of protective shell of FIG. 4A during a tangential impact.
- FIG. 5 is a partial, cross-sectional view of an embodiment of a multilayered shell structure, similar to that of FIG. 4A , configured for use as a protective body pad, e.g., a shin pad.
- a protective body pad e.g., a shin pad.
- FIG. 6 is a diagram illustrating an embodiment of a multilayer shell structure, similar to that of FIGS. 4A and 5 , configured for use as an energy-absorbing covering for the boards of a hockey rink.
- FIG. 7 is a diagram illustrating an embodiment of a multilayered shell structure, similar to those of FIGS. 4A , 5 and 6 , configured for use as an impact-absorbing bumper on a motor vehicle.
- FIG. 8 is a diagram illustrating an embodiment of a multilayered shell structure, similar to those of FIGS. 4A through 7 , configured for use as an energy-absorbing dashboard in a vehicle.
- FIG. 1A illustrates a compressible member 50 embodied in accordance with the present invention.
- the member 50 has a top surface 120 , a bottom surface 124 , and a sidewall 128 that together define a hollow inner chamber 132 .
- the bottom surface 124 has a small orifice 136 formed therein.
- airflow 144 for example, exits the small orifice 136 .
- the member 50 is formed of TPE material which, as discussed in more detail below, because of its unique properties, optimizes the impact-absorbing properties of the compressible member 50 .
- Thermoplastic elastomers or TPEs are polymer blends or compounds, which exhibit thermoplastic characteristics that enable shaping into a fabricated article when heated above their melting temperature, and which possess elastomeric properties when cooled to their designed temperature range. Accordingly, TPEs combine the beneficial properties of plastic and rubber, that is, TPEs are moldable and shapeable into a desired shape when heated and are compressible and stretchable when cooled. In contrast, neither thermoplastics nor conventional rubber alone exhibits this combination of properties.
- vulcanization a process often referred to as vulcanization. This process is slow, irreversible, and results in the individual polymer chain being linked together by covalent bonds that remain effective at normal processing temperatures. As a result, vulcanized rubbers do not become fluid when heated to these normal processing temperatures (i.e., the rubber cannot be melted). When heated well above normal processing temperatures, vulcanized rubbers eventually decompose, resulting in the loss of substantially all useful properties. Thus, conventional vulcanized rubbers cannot be formed into useful objects by processes that involve the shaping of a molten material. Such processes include injection molding, blow molding and extrusion, and are extensively used to produce useful articles from thermoplastics.
- Thermoplastics are generally not elastic when cooled and conventional rubbers are not moldable using manufacturing processes and equipment currently used for working with thermoplastics, such as injection molding and extrusion. These processes, however, are applicable for working with TPEs.
- TPEs are phase-separated systems. At least one phase is hard and solid at room temperature and another phase is elastomeric and fluid. Often the phases are chemically bonded by block or graft polymerization. In other cases, a fine dispersion of the phases is apparently sufficient.
- the hard phase gives the TPEs their strength. Without the hard phase, the elastomer phase would be free to flow under stress, and the polymers would be unusable. When the hard phase is melted, or dissolved in a solvent, flow can occur and therefore the TPE can be processed. On cooling, or upon evaporation of the solvent, the hard phase solidifies and the TPEs regain their strength.
- the hard phase of a TPE behaves similarly to the chemical crosslinks in conventional vulcanized rubbers, and the process by which the hard phase does so is often called physical crosslinking.
- the elastomer phase gives elasticity and flexibility to the TPE.
- TPEs include block copolymers containing elastomeric blocks chemically linked to hard thermoplastic blocks, and blends of these block copolymers with other materials.
- Suitable hard thermoplastic blocks include polystyrene blocks, polyurethane blocks, and polyester blocks.
- Other examples of TPEs include blends of a hard thermoplastic with a vulcanized elastomer, in which the vulcanized elastomer is present as a dispersion of small particles. These latter blends are known as thermoplastic vulcanizates or dynamic vulcanizates.
- TPEs can also be manufactured with a variety of hardness values, e.g., a soft gel or a hard 90 Shore A or greater.
- One characteristic of the TPE material is its ability to return to its original shape after the force against it removed (i.e., TPE material is said to have memory).
- Other characteristics of TPE include its resistance to tear, its receptiveness to coloring, and its rebound resilience elasticity. Rebound resilience elasticity is the ratio of regained energy in relation to the applied energy, and is expressed as a percentage ranging from 0% to 100%.
- a perfect energy absorber has a percentage of 0%; a perfectly elastic material has a percentage of 100%.
- a material with low rebound resilience elasticity absorbs most of the applied energy from an impacting object and retransmits little or none of that energy.
- a steel ball that falls upon material with low rebound resilience elasticity experiences little or no bounce; the material absorbs the energy of the falling ball.
- the ball bounces substantially if it falls upon material with high rebound resilience elasticity. This characteristic can influence the behavior of the compressible member.
- the TPE material of the compressible member 50 has a glass-transition temperature of less than ⁇ 20 degrees Fahrenheit.
- the glass-transition temperature is the temperature below which the material loses its soft and rubbery qualities.
- a TPE material with an appropriate glass-transition temperature can be selected for the compressible member 50 depending on the particular application of the member (e.g., a glass-transition temperature of 0 degrees Fahrenheit may be sufficient for baseball helmets, whereas a glass transition temperature of ⁇ 40 degrees Fahrenheit may be needed for football and hockey helmets).
- the size of the opening 136 in the compressible member 50 is preferably selected to produce a rate-sensitive response to any impact causing compression of the member 50 . For instance, if the application of force upon the member 50 is gradual or of relatively low energy, the opening 136 permits sufficient air to pass through so that the member 50 compresses gradually and presents little resistance against the force. In that case, an individual may be able to compress the member 50 manually with a moderate touch of a hand or finger.
- a further important advantage of the compressible member 50 is that it can be compressed ninety percent (90%) or more from its uncompressed thickness before “bottoming out”, i.e., before the top wall of TPE material comes in contact with the bottom wall of TPE material.
- a thickness of TPE material (equal to twice the wall thickness) remains, which, because of its compressibility, provides further energy absorption.
- the geometry of the compressible member 50 , the stiffness and elasticity of the TPE material used for its enclosure, and the venting of the member 50 can all be adjusted and optimized to provide a “softer landing” than conventional foams across a broad range of impact energy levels.
- Force/time curves for foams are bell-shaped due to the increased stiffness of foams as they are compressed which results in increasing forces with severe peaks.
- the shape of the force/time curve for foams is similar regardless of the amount of ride-down, which is dependent on the energy of the impact. For low energy impacts, the ride-down distance of foams is low and can result in concussions, even at relatively low impact energies, especially with EPS foams.
- the compressible member 50 of the invention can be engineered to allow optimal ride down for a wide range of impact energies and also to “shape” the rate at which the forces increase during the impact.
- This “shaping” of the force/time curve is accomplished by managing the air pressure in the inner chamber of the member 50 for various impact energies, something foams cannot do. The result is a flatter and broader force/time curve for the compressible member 50 which reduces the force of impact. This broader, flatter curve in essence demonstrates a “soft landing”.
- This technology allows for the manipulation of multiple engineering parameters, such as material properties, chamber geometry, chamber wall thickness, and relative configurations of outflow(s) and inflow(s). Careful calibration of the many design parameters will allow those skilled in the art to determine the optimum combination based on the particular application to which the member 50 is to be put.
- the compressible member 50 can also stretch and bend during tangential impact, as illustrated by FIG. 1C and FIG. 1D . This allows the compressible member 50 to shear in response to the tangential impacts and absorb rotational forces as well as direct forces applied normal to the top surface 120 of the member 50 .
- FIG. 1E shows the compressible member 50 following an impact. Because of its resilient nature, the tendency of the member 50 is to return to its uncompressed shape. Accordingly, after the impact force is removed from the compressible member 50 , it expands in the direction indicated by arrow 146 , consequently drawing air in through the opening 136 as indicated by arrows 148 .
- FIG. 1F illustrates a simulated sequence of expansion of a rate-sensitive compressible member 50 , as the impact force is removed.
- FIG. 2 shows a cross-section of another embodiment of a rate-sensitive compressible member 150 that is generally rectangular in shape (i.e., a strip).
- the member 150 has a top surface 160 , a bottom surface 164 , sidewalls 168 - 1 , 168 - 2 (generally, 168 ), and a hollow inner chamber 172 .
- Each sidewall 168 has a respective small opening 176 - 1 , 176 - 2 (generally, 176 ) formed therein. (Practice of the invention can be achieved with only one of the sidewalls 168 having an opening).
- airflows 184 exit the small openings 176 .
- This embodiment illustrates that a variety of shapes, for example, disc-shaped, cylindrical, and pyramidal, and the like, can be used to implement rate-sensitive compressible members of the invention capable of absorbing impact energy.
- FIG. 3 diagrammatically illustrates another version of a compressible member 250 embodied in accordance with the invention.
- the compressible member 250 differs from the prior two embodiments in that it includes separate orifices for the inflow and outflow, respectively, of air relative to its inner chamber. More specifically, the compressible member 250 includes a plurality of outflow orifices, in the form of thin slits 254 in the wall of its enclosure 252 , spaced about the circumference of the enclosure 252 .
- the compressible member 250 also includes an inflow orifice, which includes a one-way flap valve 256 , located at the bottom of the enclosure 252 .
- the one way flap valve 256 is forced closed and air is forced out of the inner chamber of the compressible member 250 through the thin slits 254 .
- the one-way flap valve 256 opens and air returns quickly to the inner chamber of the compressible member 250 through the opening of the valve.
- the outflow slits 254 are elastic, being formed directly in the TPE material of the wall of the enclosure 252 . Because of this elasticity, the slits 254 provide some resistance to opening and to the escape of the air in the inner chamber during the impact, and close resiliently and quickly following the impact.
- the slits 254 are also preferably significantly smaller in diameter that the inflow opening of the one-way flap valve 256 .
- the member 250 provides a greater degree of resistance to compression and collapse depending upon the energy level of the impact force, yet will return quickly to its uncompressed condition upon removal of the force, ready to absorb additional impacts.
- FIG. 4A is a partial cross-sectional view of an embodiment of a multilayer shell structure 230 which includes a plurality of the rate-sensitive compressible members 50 ( FIG. 1A ) disposed therein, configured as a protective helmet 200 .
- the compressible members 50 are spaced from one another and sandwiched between an outer layer 220 and an inner layer 228 .
- An internal foam liner 232 of conventional design may be disposed between the inner layer 228 and the wearer's head.
- each rate-sensitive compressible member 50 preferably aligns with an opening (not shown) in the surface of the inner layer 228 and through any internal liner 232 so that expelled or inhaled air can pass into the interior of the shell structure 230 .
- openings 136 can be on the sides of the compressible members 50 , allowing the release and return of air through the interstitial region of the shell structure 230 between the outer and inner layers 220 and 228 .
- the compressible member such as the members 150 and 250 shown above, can be substituted for the compressible members 50 in the shell structure 230 of FIG. 4A , and that two or more types or sizes of compressible members can be combined therein.
- the compressible members 50 may be secured to a single layer, either on their inside or outside, instead of being sandwiched between two layers as shown in FIG. 4A .
- the compressible members 50 instead of being separate from one another, could be interconnected by a thin web of TPE material to form a sheet-like middle layer.
- the connecting web material could also include internal passageways that communicate with the inner chambers of adjacent ones of the compressible members 50 , so that, during an impact, air passes from one chamber or member 50 to another, in addition to venting from the chambers, spreading the impact force among several members 50 .
- FIG. 4B illustrates an exemplary simulated operation of the shell structure 230 , with rate-sensitive compressible members 50 , undergoing a direct impact from an object 236 .
- the shell structure 230 operates to reduce linear-acceleration of the wearer's head 234 .
- the members 50 directly beneath the outer layer 220 at the point of impact compress.
- the compression of the shell structure 230 also causes air to exit the members 50 (arrows 238 ) and enter the interior of the shell structure 230 through the openings in the members 50 and in the inner layer 228 .
- FIG. 4C illustrates an exemplary simulated operation of the shell structure 230 , with rate-sensitive compressible members 50 , undergoing a tangential impact from an object 236 .
- the shell structure 230 operates to reduce rotational acceleration of the wearer's head 234 .
- the outer layer 220 shears with respect to the inner layer 228 in a direction of motion of the object, as illustrated by arrows 240 .
- Members 50 at the point of impact compress to some extent and shear with the outer layer 220 .
- the compression causes air to exit the members 50 and to enter the interior of the headgear.
- the combined effects of the shearing motion of the outer layer 220 and members 50 , the rate-sensitive and energy-absorbing compression of the members 50 , and the release of air into the interior of the headgear operate to reduce the rotational forces reaching the wearer's head 234 .
- the layered construction of the invention can be likewise used to construct a variety of types of protective headgear including, but not limited to, safety helmets, motorcycle helmets, bicycle helmets, ski helmets, lacrosse helmets, hockey helmets, and football helmets, batting helmets for baseball and softball, headgear for rock and mountain climbers, and headgear for boxers.
- Other applications can include helmets used on construction sites, in defense and military applications, and for underground activities.
- FIG. 5 illustrates the shell structure 230 configured as a shin pad which may be removably fastened by any suitable means e.g., elastic straps, to the lower leg of a wearer.
- the shell structure 230 may be similarly configured as a face mask, elbow pad, shoulder pads, chest protector or the like, or as a protective body pad for other sports/activities such as “extreme” and other outdoor sports, motorcross, car racing, and the like.
- FIG. 6 illustrates a shell structure 230 ′, similar to, but fabricated in larger scale and dimension than, the shell structure 230 previously described, as an impactabsorbing covering for application to the boards of a hockey rink.
- a similar shell structure 230 ′ could be used as an impact-absorbing covering for basketball gymnasium walls, racket ball walls, indoor soccer or football arenas, and other structures which enclose an athletic event.
- FIGS. 7 and 8 illustrate still another version of a shell structure 230 ′′, similar to but larger than the shell structure 230 previously described, configured as part of a vehicle bumper and dashboard, respectively.
- Other similar applications of the shell structure 230 ′′ include vehicle decking, highway barriers and the like.
Abstract
Description
- This application is a continuation-in-part application claiming priority to my co-pending U.S. patent application Ser. No. 11/059,427, filed Feb. 16, 2005, titled “Multi-Layer Air-Cushion Shell With Energy-Absorbing Layer For Use in the Construction of Protective Headgear.” The entirety of this patent application is incorporated by reference herein.
- This application also claims priority to my Provisional Application No. to 60/654,225, filed Feb. 18, 2005, titled “Compressible Air Cushion Technology For Use In Protective Body Equipment,” my Provisional Application No. 60/654,194, filed Feb. 18, 2005, titled “Compressible Air Cushion Technology For Use In Sports Arenas,” and my Provisional Application No. 60/654,128, filed Feb. 18, 2005, titled “Vehicular Uses Of Compressible Air Cushion Technology.” The entireties of these provisional applications are also incorporated by reference herein.
- This application is also related to my PCT application filed concurrently herewith, titled “Energy-Absorbing Liners For Use With Protective Headgear” (Cesari and McKenna, LLP Docket No. 104208-0019). The entirety of this application is also incorporated by reference herein.
- 1. Field of the Invention
- The invention relates generally to thin-walled, impact-absorbing compressible members. More specifically, the invention relates to an air venting, impact-absorbing compressible member, preferably fabricated from thermoplastic elastomer (TPE) material, that can be used in the construction of a wide variety of shock-absorbing and/or impact protective devices, including, without limitation, protective headgear, protective pads for other parts of the body, protective padding for sports arenas such as hockey rink boards and the like, and impact-absorbing devices for vehicles such as bumpers, dashboards and the like.
- 2. Background Information
- Concussions, also called mild traumatic brain injury, are a common, serious problem in sports known to have detrimental effects on people in the short and long term. With respect to athletes, a concussion is a temporary and reversible neurological impairment, with or without loss of consciousness. Another definition of a concussion is a traumatically induced alteration of brain function manifested by 1) an alteration of awareness or consciousness, and 2) signs and symptoms commonly associated with post-concussion syndrome, such as persistent headaches, loss of balance, and memory disturbances, to list but a few. Some athletes have had their careers abbreviated because of concussions, in particular because those who have sustained multiple concussions show a greater proclivity to further concussions and increasingly severe symptoms. Although concussions are prevalent among athletes, the study of concussions is difficult, treatment options are virtually non-existent, and “return-to-play” guidelines are speculative. Accordingly, the best current solution to concussions is prevention and minimization.
- Concussion results from a force being applied to the brain, usually the result of a direct blow to the head, which results in shearing force to the brain tissue, and a subsequent deleterious neurometabolic and neurophysiologic cascade. There are two primary types of forces experienced by the brain in an impact to the head, linear acceleration and rotational acceleration. Both types of acceleration are believed to be important in causing concussions. Decreasing the magnitude of acceleration thus decreases the force applied to the brain, and consequently reduces the risk or severity of a concussion.
- Protective headgear is well known to help protect wearers from head injury by decreasing the magnitude of acceleration (or deceleration) experienced by the wearers. Currently marketed helmets primarily address linear forces, but generally do not diminish the rotational forces experienced by the brain. Helmets fall generally into two categories: single impact helmets and multiple-impact helmets. Single-impact helmets undergo permanent deformation under impact, whereas multiple-impact helmets are capable of sustaining multiple blows. Applications of single-impact helmets include, for example, bicycling and motorcycling. Participants of contact sports, such as hockey and football, use multiple-impact helmets. Both categories of helmets have similar construction. A semi-rigid outer shell distributes the force of impact over a wide area and a compressible foam inner layer reduces the force upon the wearer's head.
- The inner layer of single-impact helmets are typically constructed of fused expanded polystyrene (EPS), a polymer impregnated with a foaming agent. EPS reduces the amount of energy that reaches the head by permanently deforming under the force of impact. To be effective against the impact, the inner layer must be sufficiently thick not to crush entirely throughout its thickness. A thick inner layer, however, requires a corresponding increase in the size of the outer shell, which increases the size and bulkiness of the helmet.
- Inner layers designed for multiple-impact helmets absorb energy through elastic and viscoelastic deformation. To absorb multiple successive hits, these helmets is need to rebound quickly to return to their original shape. Materials that rebound too quickly, however, permit some of the kinetic energy of the impact to transfer to the wearer's head. Examples of materials with positive rebound properties, also called elastic memory, include foamed polyurethane, expanded polypropylene, expanded polyethylene, and foamed vinylnitrile. Although some of these materials have desirable rebound qualities, an inner layer constructed therefrom must be sufficiently thick to prevent forceful impacts from penetrating its entire thickness. The drawback of a thick foam layer, as noted above, is the resulting bulkiness of the helmet. Moreover, the energy absorbing properties of such materials tend to diminish with increasing temperatures, whereas the positive rebound properties diminish with decreasing temperatures.
- Regardless of the particular material involved, the material properties and densities of foam inner layers in helmets have historically been selected to optimally absorb energy for impacts that are considered severe for the particular sport or activity in which the helmets are to be used. Foams are thus relatively ineffective in absorbing impact energies below the severe level. Industry safety standards currently test and certify helmet designs based on their ability to absorb high energy impacts to ensure that helmets protect wearers against severe head injuries, such as skull fractures. Recent evidence has shown that lower energy impacts result in less severe yet still damaging head injuries, typically concussions. Current laboratory certification tests are pass/fail tests, and are not designed to test for prevention of concussions.
- As such, testing of helmets to protect against concussions is being developed outside the realm of existing industry standards as the industry attempts to determine if helmets can be designed that provide universal protection against both mild and severe impacts. Several manufacturers are experimenting with various permutations of laminated foams and newer materials to broaden the range of impact energies over which the materials provide effective energy absorption. While some progress is being made, it is limited. This is due at least in part to the fact that foam materials are inherently limited in their ability to absorb energy because of their tendency to “bottom out” when compressed. Specifically, foams can be compressed downwardly only about seventy percent (70%) from their uncompressed thicknesses before they become so dense and stiff that they no longer effectively absorb impact energy. This factor is referred to as the “ride-down” point of the foam. When compressed to the is maximum “ride-down” point, a foam in a helmet is said to have “bottomed out”, and acts essentially as a rigid layer that transfers impact energy with little or no absorption directly to the wearer's head.
- There is thus a need in the industry for an improved helmet construction that can reduce the risk and severity of head injuries, including concussions, over a wide range of impact energies, without the aforementioned disadvantages of current helmet designs. There exists a similar need for structures that have improved impact-absorbing properties for use in a variety of other applications.
- The present invention provides a compressible member whose properties, configuration and construction are optimized to maximize its impact-absorbing capabilities over a wide range of impact energies.
- In accordance with the invention, a compressible member comprises a thin-walled enclosure defining a hollow inner chamber containing a volume of fluid such as air. The compressible member has at least one orifice by which fluid can vent from its inner chamber when the member experiences an impact. Preferably, the orifice is sized and positioned so that the compressible member provides a rate sensitive response to impacts, i.e., the member provides relatively low resistance to compression in response to relatively low energy impacts and relatively high resistance to compression in response to relatively high energy impacts. More than one orifice may also be provided in the compressible member so that air flows into its inner chamber following an impact at a rate that can be selected by the designer depending on the particular application of the member to be equal to, less than, or greater than the rate at which air flows out of the inner chamber during the impact.
- The thin-walled enclosure of the compressible member is preferably fabricated from blow-molded thermoplastic elastomer material (“TPE”). TPE materials are uniquely suited for the fabrication of the impact-absorbing, compressible members of the invention because they can be readily and economically molded and shaped into the desired thin-walled, hollow configuration, and because they maintain their compressibility, stretchability and structural integrity in use after experiencing repeated impacts. Additionally, because they are hollow and air filled, the TPE compressible members of the invention are capable of being compressed to substantially greater degrees than conventional foams of the type currently used in protective headgear, without “bottoming out.” This greater degree of “ride down” makes the TPE compressible members of the invention effective in the absorption of a much wider range of impact energies. Other advantages resulting from the use of TPE materials for the compressible members of the invention, and their higher “ride-down” factors, are discussed in more detail below.
- The compressible members of the invention may be assembled side-by-side in a layer, and combined with one or more layers of other materials, to form multilayer impact-absorbing shells for use in a wide variety of applications. One particularly advantageous embodiment of a protective shell structure comprises a thin outer shell layer, a compressible middle layer comprised of a plurality of the compressible members of the invention arranged in spaced apart positions, and a thin inner layer. In response to an impact to the outer shell layer, the outer layer deflects locally causing the compressible members of the middle layer to compress and vent air from their inner chambers. The inner layer is preferably provided with one or more passageways that allow the air vented from the compressible members to pass to the inside of the inner layer. The outer shell layer and the inner layer are also preferably secured to the compressible middle layer, but not directly or rigidly to each other. This allows the outer layer to shear or rotate relative to the inner layer and thus take up and absorb tangential components of the impact force.
- Multilayered shell structures which include one or more compressible members of the invention can be configured and used in the construction of a wide variety of impact-absorbing devices. Examples disclosed include helmets, protective body pads, sports arena padding, vehicle bumpers, dashboards and the like.
- The above and further advantages of this invention may be better understood by referring to the following description in conjunction with the accompanying drawings, in which like numerals indicate like structural elements and features in various figures. The drawings are not necessarily to scale or relative dimension, emphasis instead being placed upon illustrating the principles of the invention.
-
FIG. 1A is a diagram illustrating an embodiment of a compressible member of the invention having an enclosure with a bellows-like wall construction and defining a hollow inner chamber for holding a volume of fluid (e.g., air). -
FIG. 1B is a diagram of a sequence illustrating simulated effects of a high-energy impact to the compressible member ofFIG. 1A . -
FIGS. 1C and 1D are diagrams illustrating the stretching and bending (e.g., shearing) capabilities of the compressible member ofFIG. 1A . -
FIG. 1E is a diagram of the compressible member ofFIG. 1A following an impact. -
FIG. 1F is a diagram illustrating the expansion of the compressible member ofFIG. 1A to its uncompressed condition after impact force is removed. -
FIG. 2 is a diagram of another embodiment of a compressible member of the invention having a generally rectangular shape and configuration. -
FIG. 3 is a diagram of a sequence illustrating simulated effects of an impact on another embodiment of a compressible member of the invention having separate in-flow and outflow orifices for the fluid contained in its inner chamber. -
FIG. 4A is a partial, cross-sectional view of an embodiment of a multilayer shell structure, which includes a layer formed of a plurality of compressible members embodied in accordance with the invention, configured to function as a protective helmet for a wearer's head. -
FIG. 4B is a diagram illustrating the operation of protective shell ofFIG. 4A during a direct impact. -
FIG. 4C is a diagram illustrating the operation of protective shell ofFIG. 4A during a tangential impact. -
FIG. 5 is a partial, cross-sectional view of an embodiment of a multilayered shell structure, similar to that ofFIG. 4A , configured for use as a protective body pad, e.g., a shin pad. -
FIG. 6 is a diagram illustrating an embodiment of a multilayer shell structure, similar to that ofFIGS. 4A and 5 , configured for use as an energy-absorbing covering for the boards of a hockey rink. -
FIG. 7 is a diagram illustrating an embodiment of a multilayered shell structure, similar to those ofFIGS. 4A , 5 and 6, configured for use as an impact-absorbing bumper on a motor vehicle. -
FIG. 8 is a diagram illustrating an embodiment of a multilayered shell structure, similar to those ofFIGS. 4A through 7 , configured for use as an energy-absorbing dashboard in a vehicle. -
FIG. 1A illustrates acompressible member 50 embodied in accordance with the present invention. Themember 50 has atop surface 120, abottom surface 124, and asidewall 128 that together define a hollowinner chamber 132. Thebottom surface 124 has asmall orifice 136 formed therein. When themember 50 compresses in the general direction indicated byarrow 140,airflow 144, for example, exits thesmall orifice 136. Themember 50 is formed of TPE material which, as discussed in more detail below, because of its unique properties, optimizes the impact-absorbing properties of thecompressible member 50. - Thermoplastic elastomers or TPEs are polymer blends or compounds, which exhibit thermoplastic characteristics that enable shaping into a fabricated article when heated above their melting temperature, and which possess elastomeric properties when cooled to their designed temperature range. Accordingly, TPEs combine the beneficial properties of plastic and rubber, that is, TPEs are moldable and shapeable into a desired shape when heated and are compressible and stretchable when cooled. In contrast, neither thermoplastics nor conventional rubber alone exhibits this combination of properties.
- To achieve satisfactory purposes, conventional rubbers must be chemically crosslinked, a process often referred to as vulcanization. This process is slow, irreversible, and results in the individual polymer chain being linked together by covalent bonds that remain effective at normal processing temperatures. As a result, vulcanized rubbers do not become fluid when heated to these normal processing temperatures (i.e., the rubber cannot be melted). When heated well above normal processing temperatures, vulcanized rubbers eventually decompose, resulting in the loss of substantially all useful properties. Thus, conventional vulcanized rubbers cannot be formed into useful objects by processes that involve the shaping of a molten material. Such processes include injection molding, blow molding and extrusion, and are extensively used to produce useful articles from thermoplastics.
- Thermoplastics are generally not elastic when cooled and conventional rubbers are not moldable using manufacturing processes and equipment currently used for working with thermoplastics, such as injection molding and extrusion. These processes, however, are applicable for working with TPEs.
- Most TPEs have a common feature: they are phase-separated systems. At least one phase is hard and solid at room temperature and another phase is elastomeric and fluid. Often the phases are chemically bonded by block or graft polymerization. In other cases, a fine dispersion of the phases is apparently sufficient. The hard phase gives the TPEs their strength. Without the hard phase, the elastomer phase would be free to flow under stress, and the polymers would be unusable. When the hard phase is melted, or dissolved in a solvent, flow can occur and therefore the TPE can be processed. On cooling, or upon evaporation of the solvent, the hard phase solidifies and the TPEs regain their strength. Thus, in one sense, the hard phase of a TPE behaves similarly to the chemical crosslinks in conventional vulcanized rubbers, and the process by which the hard phase does so is often called physical crosslinking. At the same time, the elastomer phase gives elasticity and flexibility to the TPE.
- Examples of TPEs include block copolymers containing elastomeric blocks chemically linked to hard thermoplastic blocks, and blends of these block copolymers with other materials. Suitable hard thermoplastic blocks include polystyrene blocks, polyurethane blocks, and polyester blocks. Other examples of TPEs include blends of a hard thermoplastic with a vulcanized elastomer, in which the vulcanized elastomer is present as a dispersion of small particles. These latter blends are known as thermoplastic vulcanizates or dynamic vulcanizates.
- TPEs can also be manufactured with a variety of hardness values, e.g., a soft gel or a hard 90 Shore A or greater. One characteristic of the TPE material is its ability to return to its original shape after the force against it removed (i.e., TPE material is said to have memory). Other characteristics of TPE include its resistance to tear, its receptiveness to coloring, and its rebound resilience elasticity. Rebound resilience elasticity is the ratio of regained energy in relation to the applied energy, and is expressed as a percentage ranging from 0% to 100%. A perfect energy absorber has a percentage of 0%; a perfectly elastic material has a percentage of 100%. In general, a material with low rebound resilience elasticity absorbs most of the applied energy from an impacting object and retransmits little or none of that energy. To illustrate, a steel ball that falls upon material with low rebound resilience elasticity experiences little or no bounce; the material absorbs the energy of the falling ball. In contrast, the ball bounces substantially if it falls upon material with high rebound resilience elasticity. This characteristic can influence the behavior of the compressible member.
- Another advantage of these TPEs is that their favorable characteristics may exist over a wide range of temperatures. Preferably, the TPE material of the
compressible member 50 has a glass-transition temperature of less than −20 degrees Fahrenheit. The glass-transition temperature is the temperature below which the material loses its soft and rubbery qualities. A TPE material with an appropriate glass-transition temperature can be selected for thecompressible member 50 depending on the particular application of the member (e.g., a glass-transition temperature of 0 degrees Fahrenheit may be sufficient for baseball helmets, whereas a glass transition temperature of −40 degrees Fahrenheit may be needed for football and hockey helmets). - The size of the
opening 136 in thecompressible member 50 is preferably selected to produce a rate-sensitive response to any impact causing compression of themember 50. For instance, if the application of force upon themember 50 is gradual or of relatively low energy, the opening 136 permits sufficient air to pass through so that themember 50 compresses gradually and presents little resistance against the force. In that case, an individual may be able to compress themember 50 manually with a moderate touch of a hand or finger. - If, as illustrated by
FIG. 1B , the application of force upon themember 50 occurs instantaneously or is of relatively high energy, laminar or turbulent air flows within theinner chamber 132. The size of theopening 136, which is small relative to the volume of air moved by the force, restricts the emission of the turbulent or laminar air from thechamber 132 and thus causes resistance within thechamber 132. Eventually the resistance is overcome and air flows out, and during this process, a portion of the impact energy is also converted to heat. This variable response, dependent upon the energy input, is termed a rate-sensitive or a non-linear response. - A further important advantage of the
compressible member 50 is that it can be compressed ninety percent (90%) or more from its uncompressed thickness before “bottoming out”, i.e., before the top wall of TPE material comes in contact with the bottom wall of TPE material. This increased “ride-down” factor compared to conventional foams, which have ride-down factors of only about 70%, increases the distance over which impacts are effectively absorbed and, as a result, decreases the force trans-ferred through thecompressible member 50 proportionately to this increased distance. Even when thecompressible member 50 “bottoms out”, a thickness of TPE material (equal to twice the wall thickness) remains, which, because of its compressibility, provides further energy absorption. - Additionally, the geometry of the
compressible member 50, the stiffness and elasticity of the TPE material used for its enclosure, and the venting of themember 50 can all be adjusted and optimized to provide a “softer landing” than conventional foams across a broad range of impact energy levels. Force/time curves for foams are bell-shaped due to the increased stiffness of foams as they are compressed which results in increasing forces with severe peaks. The shape of the force/time curve for foams is similar regardless of the amount of ride-down, which is dependent on the energy of the impact. For low energy impacts, the ride-down distance of foams is low and can result in concussions, even at relatively low impact energies, especially with EPS foams. - The
compressible member 50 of the invention, on the other hand, can be engineered to allow optimal ride down for a wide range of impact energies and also to “shape” the rate at which the forces increase during the impact. This “shaping” of the force/time curve is accomplished by managing the air pressure in the inner chamber of themember 50 for various impact energies, something foams cannot do. The result is a flatter and broader force/time curve for thecompressible member 50 which reduces the force of impact. This broader, flatter curve in essence demonstrates a “soft landing”. - This technology allows for the manipulation of multiple engineering parameters, such as material properties, chamber geometry, chamber wall thickness, and relative configurations of outflow(s) and inflow(s). Careful calibration of the many design parameters will allow those skilled in the art to determine the optimum combination based on the particular application to which the
member 50 is to be put. - In addition to providing this rate-sensitive response, the
compressible member 50 can also stretch and bend during tangential impact, as illustrated byFIG. 1C andFIG. 1D . This allows thecompressible member 50 to shear in response to the tangential impacts and absorb rotational forces as well as direct forces applied normal to thetop surface 120 of themember 50. -
FIG. 1E shows thecompressible member 50 following an impact. Because of its resilient nature, the tendency of themember 50 is to return to its uncompressed shape. Accordingly, after the impact force is removed from thecompressible member 50, it expands in the direction indicated byarrow 146, consequently drawing air in through theopening 136 as indicated byarrows 148.FIG. 1F illustrates a simulated sequence of expansion of a rate-sensitivecompressible member 50, as the impact force is removed. -
FIG. 2 shows a cross-section of another embodiment of a rate-sensitivecompressible member 150 that is generally rectangular in shape (i.e., a strip). Themember 150 has atop surface 160, abottom surface 164, sidewalls 168-1, 168-2 (generally, 168), and a hollowinner chamber 172. Each sidewall 168 has a respective small opening 176-1, 176-2 (generally, 176) formed therein. (Practice of the invention can be achieved with only one of the sidewalls 168 having an opening). When themember 150 compresses generally in the direction indicated byarrow 180,airflows 184 exit the small openings 176. This embodiment illustrates that a variety of shapes, for example, disc-shaped, cylindrical, and pyramidal, and the like, can be used to implement rate-sensitive compressible members of the invention capable of absorbing impact energy. -
FIG. 3 diagrammatically illustrates another version of acompressible member 250 embodied in accordance with the invention. Thecompressible member 250 differs from the prior two embodiments in that it includes separate orifices for the inflow and outflow, respectively, of air relative to its inner chamber. More specifically, thecompressible member 250 includes a plurality of outflow orifices, in the form ofthin slits 254 in the wall of itsenclosure 252, spaced about the circumference of theenclosure 252. Thecompressible member 250 also includes an inflow orifice, which includes a one-way flap valve 256, located at the bottom of theenclosure 252. - As the sequence of
FIG. 3 illustrates, moving from left to right in the figure, upon impact, the oneway flap valve 256 is forced closed and air is forced out of the inner chamber of thecompressible member 250 through thethin slits 254. Upon removal of the force, the one-way flap valve 256 opens and air returns quickly to the inner chamber of thecompressible member 250 through the opening of the valve. - To further enhance the “rate-sensitive” response of the
compressible member 250 of this embodiment, the outflow slits 254 are elastic, being formed directly in the TPE material of the wall of theenclosure 252. Because of this elasticity, theslits 254 provide some resistance to opening and to the escape of the air in the inner chamber during the impact, and close resiliently and quickly following the impact. Theslits 254 are also preferably significantly smaller in diameter that the inflow opening of the one-way flap valve 256. As a result, themember 250 provides a greater degree of resistance to compression and collapse depending upon the energy level of the impact force, yet will return quickly to its uncompressed condition upon removal of the force, ready to absorb additional impacts. -
FIG. 4A is a partial cross-sectional view of an embodiment of amultilayer shell structure 230 which includes a plurality of the rate-sensitive compressible members 50 (FIG. 1A ) disposed therein, configured as aprotective helmet 200. In this particular embodiment shown, thecompressible members 50 are spaced from one another and sandwiched between anouter layer 220 and aninner layer 228. Aninternal foam liner 232 of conventional design may be disposed between theinner layer 228 and the wearer's head. - In the
shell structure 230 ofFIG. 4A , theorifice 136 of each rate-sensitivecompressible member 50 preferably aligns with an opening (not shown) in the surface of theinner layer 228 and through anyinternal liner 232 so that expelled or inhaled air can pass into the interior of theshell structure 230. Similarly,such openings 136 can be on the sides of thecompressible members 50, allowing the release and return of air through the interstitial region of theshell structure 230 between the outer andinner layers - Those desiring further details of the construction of a shell structure such as
shell structure 230, and its configuration as a protective helmet, are referred to my copending U.S. patent application Ser. No. 11/059,427, filed Feb. 16, 2005, and my related application filed concurrently herewith, titled “EnergyAbsorbing Inner Liners For Use With Protective Headgear” (Cesari and McKenna, LLP Docket No. 104208-0019), which, as noted above, are incorporated by reference herein. - Those skilled in the art will appreciate that other embodiments of the compressible member, such as the
members compressible members 50 in theshell structure 230 ofFIG. 4A , and that two or more types or sizes of compressible members can be combined therein. Those skilled in the art will also appreciate that modifications can be made to theshell structure 230 without departing from the scope of the invention. For example, thecompressible members 50 may be secured to a single layer, either on their inside or outside, instead of being sandwiched between two layers as shown inFIG. 4A . Additionally, thecompressible members 50, instead of being separate from one another, could be interconnected by a thin web of TPE material to form a sheet-like middle layer. The connecting web material could also include internal passageways that communicate with the inner chambers of adjacent ones of thecompressible members 50, so that, during an impact, air passes from one chamber ormember 50 to another, in addition to venting from the chambers, spreading the impact force amongseveral members 50. -
FIG. 4B illustrates an exemplary simulated operation of theshell structure 230, with rate-sensitivecompressible members 50, undergoing a direct impact from anobject 236. In this example, theshell structure 230 operates to reduce linear-acceleration of the wearer'shead 234. When theobject 236 strikes the outer layer, themembers 50 directly beneath theouter layer 220 at the point of impact compress. The compression of theshell structure 230 also causes air to exit the members 50 (arrows 238) and enter the interior of theshell structure 230 through the openings in themembers 50 and in theinner layer 228. -
FIG. 4C illustrates an exemplary simulated operation of theshell structure 230, with rate-sensitivecompressible members 50, undergoing a tangential impact from anobject 236. In this example, theshell structure 230 operates to reduce rotational acceleration of the wearer'shead 234. When struck by an object tangentially, theouter layer 220 shears with respect to theinner layer 228 in a direction of motion of the object, as illustrated byarrows 240.Members 50 at the point of impact compress to some extent and shear with theouter layer 220. As with the example ofFIG. 4B , the compression causes air to exit themembers 50 and to enter the interior of the headgear. The combined effects of the shearing motion of theouter layer 220 andmembers 50, the rate-sensitive and energy-absorbing compression of themembers 50, and the release of air into the interior of the headgear operate to reduce the rotational forces reaching the wearer'shead 234. - The layered construction of the invention can be likewise used to construct a variety of types of protective headgear including, but not limited to, safety helmets, motorcycle helmets, bicycle helmets, ski helmets, lacrosse helmets, hockey helmets, and football helmets, batting helmets for baseball and softball, headgear for rock and mountain climbers, and headgear for boxers. Other applications can include helmets used on construction sites, in defense and military applications, and for underground activities.
- Although the foregoing description focuses primarily on protective headgear, it is to be understood that the compressible members of the invention can be used in other types of equipment used for sports activities or other applications.
- By way of example,
FIG. 5 illustrates theshell structure 230 configured as a shin pad which may be removably fastened by any suitable means e.g., elastic straps, to the lower leg of a wearer. Those skilled in the art will appreciate that theshell structure 230 may be similarly configured as a face mask, elbow pad, shoulder pads, chest protector or the like, or as a protective body pad for other sports/activities such as “extreme” and other outdoor sports, motorcross, car racing, and the like. -
FIG. 6 illustrates ashell structure 230′, similar to, but fabricated in larger scale and dimension than, theshell structure 230 previously described, as an impactabsorbing covering for application to the boards of a hockey rink. Asimilar shell structure 230′ could be used as an impact-absorbing covering for basketball gymnasium walls, racket ball walls, indoor soccer or football arenas, and other structures which enclose an athletic event. -
FIGS. 7 and 8 illustrate still another version of ashell structure 230″, similar to but larger than theshell structure 230 previously described, configured as part of a vehicle bumper and dashboard, respectively. Other similar applications of theshell structure 230″ include vehicle decking, highway barriers and the like. - While the invention has been shown and described with reference to specific preferred embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the following claims.
Claims (18)
Priority Applications (2)
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US11/815,486 US20080256686A1 (en) | 2005-02-16 | 2006-02-16 | Air Venting, Impact-Absorbing Compressible Members |
US14/295,507 US9683622B2 (en) | 2004-04-21 | 2014-06-04 | Air venting, impact-absorbing compressible members |
Applications Claiming Priority (6)
Application Number | Priority Date | Filing Date | Title |
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US11/059,427 US20060059606A1 (en) | 2004-09-22 | 2005-02-16 | Multilayer air-cushion shell with energy-absorbing layer for use in the construction of protective headgear |
US65412805P | 2005-02-18 | 2005-02-18 | |
US65422505P | 2005-02-18 | 2005-02-18 | |
US65419405P | 2005-02-18 | 2005-02-18 | |
PCT/US2006/005857 WO2006089235A1 (en) | 2005-02-16 | 2006-02-16 | Air venting, impact-absorbing compressible members |
US11/815,486 US20080256686A1 (en) | 2005-02-16 | 2006-02-16 | Air Venting, Impact-Absorbing Compressible Members |
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PCT/US2006/005857 A-371-Of-International WO2006089235A1 (en) | 2004-04-21 | 2006-02-16 | Air venting, impact-absorbing compressible members |
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US11399589B2 (en) | 2018-08-16 | 2022-08-02 | Riddell, Inc. | System and method for designing and manufacturing a protective helmet tailored to a selected group of helmet wearers |
US11167198B2 (en) | 2018-11-21 | 2021-11-09 | Riddell, Inc. | Football helmet with components additively manufactured to manage impact forces |
USD927084S1 (en) | 2018-11-22 | 2021-08-03 | Riddell, Inc. | Pad member of an internal padding assembly of a protective sports helmet |
US11812811B2 (en) * | 2018-11-23 | 2023-11-14 | Michael Baker | Energy diverting football helmet |
US11341831B2 (en) | 2020-01-22 | 2022-05-24 | James Kelly | Device and system for ultrasonic transmission of accelerometer data |
CN112277854A (en) * | 2020-11-02 | 2021-01-29 | 常州市凯德汽车部件有限公司 | Automobile front bumper assembly |
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WO2006089235A1 (en) | 2006-08-24 |
US20150008085A1 (en) | 2015-01-08 |
US9683622B2 (en) | 2017-06-20 |
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