IMPACT RESISTANT FACE SHIELD |
|||||||
| 申请号 | EP96922665.3 | 申请日 | 1996-07-03 | 公开(公告)号 | EP0844833B1 | 公开(公告)日 | 2003-05-07 |
| 申请人 | OAKLEY, INC.; | 发明人 | JARVIS, Edward, C.; | ||||
| 摘要 | An impact resistant face shield that includes a single formed arcuate lens portion (12) that, in a first orientation, has a first curvature (16) extending in a horizontal direction and a second curvature (18) extending in a vertical direction. The lens portion has a top portion and a bottom portion (20) that extends relatively inwardly toward the face of the wearer relative to an intermediate portion disposed between the top and bottom portions. Each curvature of the lens defines an arc of a circle having a substantially uniform radius to produce nominal levels of distortion, thereby reducing the prism effects created by the lens, and providing an optically corrected viewing window. | ||||||
| 权利要求 | |||||||
| 说明书全文 | This invention relates to mechanical protective devices, and more particularly to impact resistant face shields for use in protecting the face of an individual. Today, sports are more popular than ever. This increase in popularity has resulted in an increase in the number of amateur and professional sport participants. Unfortunately, increased participation has resulted in an increase in the number of injuries suffered by individuals, and particularly in the number of facial injuries. Consequently, some sports now recommend and/or require the use of face shields or other facial protective devices when participating in the sport. One such sport is hockey. Conventional face shields suitable for use in sports, such as those manufactured by Itech Sports Products, Inc. under the trade designation ITECH® Type IV sports protector, typically consist of a transparent polycarbonate blank that is formed or molded into a convex shield, which is adapted for mounting to existing sport helmets. The shield, when mounted to the helmet, extends generally outwardly and away from the wearer's face. As a result of this mounting configuration, objects located in the external environment appear at least partially distorted. Thus, the molded polycarbonate blank introduces some distortion over a portion of the individual's field of view. The distorting effects of conventional face shields creates a unique set of problems for the wearer. The shield can cause strain on the wearer's eyes, which over a period of time can have deleterious effects. Additionally, rapidly viewing objects through the face shield and conversely not through the face shield produces further eye strain by requiring the individual to focus differently for each different field of view. U. S. Patent No. 3,897,597 discloses an arcuately molded face shield for mounting to sporting helmets suitable for use in sporting events for shielding a substantial portion of a sport participant's face against mechanical impact and having a thickness effective enough to survive impact without cracking. One of the limitations of this conventional face shield is that objects not centrally located within the field of view appear to be distorted. Due to the foregoing and other shortcomings of existing face shields, an object of this invention is to provide a face shield that reduces optical distortion. Another object of this invention is to provide a protective face shield that has relatively high optical clarity and resolution. Still another object of the invention is to provide a face shield that reduces the eye strain. Yet another object of the invention is to provide a face shield that is relatively strong and durable and relatively lightweight. Other general and more specific objects of the invention will in part be obvious and will in part appear from the drawings and description which follow. The objects of the present invention are achieved with the features of the claims. The present invention relates to protective face shields that provide for higher image resolution and contrast during use. The improved contrast and resolution is achieved by providing an impact resistant face shield that addresses optical and mechanical concerns. Specifically, the present invention provides for an optically-correct face shield comprising the features of claim 1. Preferred embodiments of the invention are described in the dependent claims. The invention attains an optically correct face shield by structuring the face shield to have an inner radius, an outer radius, a thickness and a refractive index, where the foregoing are mated to provide for a shield that lies between a truly plano lens and a lens having concentric geometry, e.g., constant thickness. The optical qualities of the lens are such that the prism and dioptric power are relatively low, and preferably between about 0.01 diopter and about 0.10 diopter. The face shield preferably includes a single formed acruate lens portion that, in a first orientation, has a first curvature extending in a horizontal direction and a second curvature extending in a vertical direction. The lens portion has a top portion and a bottom portion that extends relatively inwardly towards the face of the wearer relative to an intermediate portion disposed between the top and bottom portions. Each curvature of the lens defines an arc of a circle having a substantially uniform radius to produce nominal levels of distortion, thereby reducing the prism effects, e.g., non-uniform distortions of the field, created by the lens, and providing an optically corrected viewing window. According to one aspect, the lens portion of the face shield of the present invention has a thickness defined between outer and inner surfaces. The surfaces preferably have different radii of curvatures about centers that are shifted relative to each other. This eccentricity shifts one surface with respect to the other, to create a curved lens that has a thickness d that varies along the arc length of the face shield. The diametral lines of the surfaces are shifted such that the inner surface is moved back from a concentric position, thickening the central portion of the lens, and creating edges that are thinner relative to the central thickened region. This variable thickness, and particularly the thinning effect of the lens at the edges, optically corrects the lens at the peripheral regions by reducing the occurrence of prismatic deviations and overall prism imbalance. According to another aspect of the invention, the shield preferably includes a frame structure that is formed about at least a portion of the lens. According to one embodiment, the frame includes ventilation apertures formed in a top portion of the face shield. The ventilation apertures allow air to flow through the mask to provide for proper ventilation of the shield to resist or remove fogging. According to another practice of the invention, the face shield surrounds a substantial portion of the wearer's face when situated properly thereabout. In this position, the inside surface of the lens is substantially non-oblique relative to the wearer's face and the wearer's field of view is substantially normal to the inside surface of the lens about most of the field of view. Additionally, the face shield extends in the vertical direction a distance sufficient to include a substantial portion of the downward field of view without imposing upon the wearer the distortions and aberrations created by the edges of the shield. The present invention further pertains to a face protective shield having a shield body formed of strong clear polymeric material having a peripheral region and a central region. The peripheral region includes an attachment element for securing the shield body in front of the wearer's face. The central region is preferably formed as a viewing window sized to extend around in front of the wearer's face. According to one aspect, the shield has a thickness effective to survive impact without cracking and curves in both horizontal and vertical planes over substantially the entire central region to introduce a degree of lensing and correct viewing aberrations. According to another aspect, the central region has front and rear surfaces. The front surface has a radius of curvature Rf greater than the rear surface radius of curvature Rr, such that Rf- Rr = δ. According to still another aspect, the centers of curvature of the front and rear surfaces are spaced closer than δ. According to another aspect, the lensing power of the shield is negative in at least the horizontal plane. Other general and more specific objects of the invention will in part be obvious and will in part be evident from the drawings and description which follow. The foregoing and other objects, features and advantages of the invention will be apparent from the following description and apparent from the accompanying drawings, in which like reference characters refer to the same parts throughout the different views. The drawings illustrate principles of the invention and, although not to scale, show relative dimensions.
FIGURES 14 illustrate the general principles of the protective face shield of the present invention. These general principles pertain to each of the additional face shield embodiments set forth and described below. FIGURES 1 and 2 illustrate a first embodiment of the face shield 10 of the present invention. The face shield 10 includes a unitary curved lens portion 12 that is encompassed by a beaded frame structure 14 disposed about a substantial portion of the periphery of the lens. Preferably, the beaded frame 14 is integrally molded with the lens portion 12. The lens portion 12 has a first or horizontal curvature 16 (as seen in a horizontal plane), and a second vertical curvature 18. The horizontal curvature 16 has a circular cross-section and approximates a complete semi-circle, e.g., subtends an arc of about 180°, and thus provides a wrap-around face shield that covers and protects the face of the wearer while providing a window portion that extends about a substantial portion of the wearer's potential field of view. The potential field of view is substantially greater than the actual view of any moment, and includes the extremes at each side that become visible as the wearer rotates his eyes, but without re-orienting his head. The vertical curvature 18 has a circular cross-section, and a bottom portion 20 that extends relatively inwardly towards the face of the wearer relative to an intermediate portion 22 of the lens 12. The wrap-around configuration of the lens 12 in both the horizontal and vertical directions provides a single view pane through which the wearer observes the external environment. This configuration allows the wearer to observe objects at any location through the lens portion 12 without requiring the wearer to change viewing environments, for example, view one object through the lens and another object at a different location outside of the view frame of the lens. A significant advantage of this is that it reduces eye strain by allowing the wearer to view the environment through a single wrap-around window. It is known that light rays striking a piano lens of known construction at a selected angle θ emerge from the lens at the angle θ but offset by a selected displacement α determinable by known formulae, as shown in FIGURE 3. For example, a light ray 24 that impinges upon the lens is offset the distance α, which is dependent upon the lens thickness, the angle of incidence and the refractive index of the lens material. The light ray 24 exits the lens at the angle of incidence θ. These variations in the refraction of light introduce distortions into the field of view, particularly when viewing objects along a sight line that intersects the window obliquely. Thus, an object located at or near the periphery of the field of view may appear elongated and/or shifted in space relative to the actual spatial location of the object. This phenomena represents a common problem with conventional impact resistant face shields. Since the shields must be sufficiently thick to attain strength, they necessarily introduce distortion effects. Referring again to FIGURES 1 and 2, each curvature 16 and 18 of the lens portion 12 defines an arc of a circle having a substantially uniform radius. This dual-curvature configuration provides a viewing window that is oriented almost normal to the line of sight as the wearer's eyes rotate to view objects. It produces only nominal levels of distortion, reducing the prism effects, e.g., non-uniform distortions of the field, created by the lens portion 12, and provides an optically corrected viewing window. Although a variety of radii might accrue the advatages of the present invention, the radius of the hotizontal curvature 16 is preferably in the range between abouts 74.2mm (3 inches) and about 127 mm (5 inches), and most preferably is about 101.4mm (4 inches). The radius of the vertical curvature is preferably in the range between about 145.1 mm (6.5 inches) and about 215.9mm (8.5 inches), and most preferably is about 188.0mm (7.4 inches). The foregoing radius dimensions represent the distance from arbitrary center of curvature points to the arc defined by each curvature of the illustrated face shield 10. This construction defines a uniform distance to allow a full and unobstructed viewing hemisphere. Those of ordinary skill will readily recognize that the lens portion 12 of the face shield 10 of the present invention has a thickness defined between outer and inner surfaces, and thus could be defined as having merely a single radius only when it has constant thickness. However, preferably, as shown in FIGURE 4, which is a cross-sectional view of the face shield 10 of FIGURE 2 taken along line 4-4, the lens portion 12 has a thickness or depth dimension dθ along its entire are length, which is defined between an outer facing (convex) surface 26 having a radius R1 and an inner facing (concave) surface 28 having a radius R2. In this embodiment, the radius R2 is less than the radius R1 and eccentric relative thereto. Specifically, the surfaces 26 and 28 have different radii of curvatures about centers that are shifted relative to each other. This eccentricity shifts one surface with respect to the other, to create a curved lens that has a thickness dθ that varies monotonically away from a centerpoint, e.g., is tapered toward the edge, along the arc length of the face shield. Preferably, the inner concave surface 28 is not completely circular, but rather one surface at least is non-diametral to produce a minimum thickness dminat the edges 30 of the face shield. Furthermore, the diametral lines of the two surfaces are shifted such that the rear surface is moved back from a concentric position, thickening the central portion of the lens to produce a maximum thickness dmax at or near centerline 32. As illustrated, the distance between the centerpoint C1 for radius R1 and the centerpoint C2 for radius R2 is preferably between 1 and 2 mm, but those of ordinary skill will recognize that this distance can vary depending upon the desired thickness of the shield at the center or at the edges of the lens in order to achieve a particular degree of bending, breaking, tensile or impact strength. According to one practice the absolute value of the difference in centerpoints is less than the lens thickness dθ. As set forth above, plano (or constant-thickness) lenses introduce distortions or prismatic deviations into the field of view of the wearer by non-uniformly shifting light entering and exiting the lens. Lenses having truly concentric inner and outer radii, e.g., a plano lens bent into a circular shape, introduce prismatic deviations. This prism effect distorts, e.g., elongates or displaces, objects viewed by the wearer and this distortion is particularly exaggerated at the peripheral viewing regions of the lens. With reference to the present invention, the variable thickness dθ, and particularly the thinning effect of the lens at the edge regions 30, optically corrects the lens at the peripheral regions by reducing the occurrence of prismatic deviations and overall prism imbalance. Specifically, the lensing effect of the lens 12 in conjunction with the relatively thinner edge regions 30 introduce relatively low levels of distortion and serve to optically correct the view over substantially the entire lens area. Thus, the term "optically-correct" as used herein is intended to refer to the reduction in prismatic deviations created by the particular design and geometry of each embodiment of the face shield of the invention as described above in relation to FIGURES 1 and 2 and below in relation to FIGURES 5-7, and further is intended to include a face shield that exhibits a relatively low dioptric power and a relatively low prism power over a substantial portion of the wearer's field of view. Preferably, the shield includes only a few hundredths of a diopter of controlled dioptric power, and has a negative lensing effect which compensates for the prism aberrations. Furthermore, by shifting the front and rear curved surfaces, a structural thickening is achieved in a central region of low distortion, allowing a lower prism thickness to be safely employed peripherally. According to the face shield embodiment of FIGURES 1 and 2, the thickness dmax of the lens 12 at the centerline 32 is about 4 mm (0.157 inches) with a minimum thickness dmin at the edges 30 ranging between about 2 mm (0.0787 inches) and about 2.7 mm (0.102 inches). According to one practice, the lens thickness dθ varies smoothly with increasing angle from dmax to dmin. The radius R1 preferably ranges between about 95 mm and about 110 mm, and most preferably between about 100 mm and about 105 mm, and the radius R2 ranges between about 96 mm and about 103 mm, and most preferably is about 100 mm. For the vertical curvature 18 of the lens, R1 preferably ranges between about 180 mm and 192 mm, and most preferably is about 187 mm, and R2 ranges between about 178 mm and about 186 mm, and most preferably is about 183 mm. Furthermore, the illustrated face shield 10 has a height H1 that varies about the length of the shield in the horizontal direction. The vertical height H1 preferably varies between about 3.75 inches and about 4.75 inches along the curvature of the shield, and preferably is about 4.25 inches as measured at the centerline. Referring again to FIGURES 1 and 2, the illustrated frame structure 14 includes ventilation apertures 40 formed in a peripheral band of the top portion 34 of the face shield 10. The ventilation apertures allow air to flow through the mask, either in an upward or downward direction, to provide for proper ventilation of the shield to resist or remove fogging. The size and number of the ventilation apertures is not important to the teachings of the present invention. A thickness web may provide added strength about the ventilation openings. According to one practice, the face shield can be mounted to the head of the wearer or to various sport helmets by known retention mechanisms. For example, the face shield or protector 10 can be attached to a hockey helmet by way of conventional securing and mounting pins, hooks, straps, and like retention elements. One end of a securing strap preferably seats in the strap aperture 42 formed on either side of the frame member 14 to help secure the face shield to the helmet and about the face of the wearer. When mounted on the helmet, the face shield 10 surrounds a substantial portion of the wearer's face, and particularly surrounds the upper portion of the face as well as the nose and portions of the cheeks. More particularly, the shield surrounds the face such that the inside surface of the lens is substantially non-oblique relative to the wearer's face and the wearer's field of view is substantially normal to the inside surface of the lens portion 12 of the shield 10 about most of the field of view. Additionally, the face shield 10 extends in the vertical direction a distance sufficient to include a substantial portion of the downward field of view without imposing upon the wearer the distortions and aberrations created by the edges of the shield. Specifically, the bottom portion of the face shield extends inwardly towards the wearer's face to allow the wearer to view the external environment through the lens portion at close distances, and through a contour which reduces obliqueness of incident rays. The face shield 10 is composed of a transparent impact resistant material, such as polycarbonate, which has a refractive index of 1.586 at the helium d line. The face shield preferably meets selected strength and impact tests, including the Canadian impact testing standard CSA § 5.3.4. Those of ordinary skill will readily recognize that other suitable polymer materials can be used. FIGURES 5 and 6 illustrate a second embodiment of the face shield of the present invention. The illustrated face shield 100 has a unitary lens portion 102 that has a top portion 104 and a bottom portion 106. The lens portion 102 also includes a horizontal curvature and a vertical curvature that exhibit the same properties as those described above in relation to the face shield 10 of FIGURES 1 and 2. The horizontal curvature of the face shield approximates a semi-circle and thus provides a wrap-around face shield that covers and protects the face of the wearer while providing a window portion that extends about a substantial portion of the wearer's field of view. This wrap-around configuration of the lens 102 in both the horizontal and vertical directions provides a single view pane through which the wearer observes the external environment. This configuration allows the wearer to observe objects at any location through the lens portion 102 without requiring the wearer to change viewing environments, for example, view one object through the lens and another object at a different location outside of the view frame of the lens. According to one practice, the radius of the horizontal curvature is preferably between about 3.25 inches and about 5.25 inches, and the radius of the vertical curvature is preferably in the range between about 6.35 inches and about 8.35 inches, and most preferably is about 7.4 inches. The foregoing radius dimensions represent the distance from an arbitrary center point to the arc defined by each curvature of the illustrated face shield 100. The illustrated face shield 100 also has a thickness dθ that is defined by outer and inner curved surfaces, as described above in relation to FIGURES 1-2 and 4. the illustrated face shield 100 preferably has an outer radius R1 that ranges between about 95 mm and about 110 mm, and most preferably is about 103 mm, and the radius R2 ranges between about 96 mm and about 103 mm, and most preferably is about 101 mm. For the vertical curvature of the lens 102, R1 preferably ranges between about 180 mm and 192 mm, and most preferably is about 187 mm, and R2 ranges between about 178 mm and about 186 mm, and most preferably is about 183 mm. The illustrated face shield 100 further has a height H1 that varies about the length of the shield in the horizontal direction. The height H1 preferably varies between about 2.3 inches and about 4.3 inches, and preferably is about 3.3 inches at the center. The optical and physical design properties described above in relation to shield 10 accrue to this embodiment to form an optically correct face shield that withstands the impact of foreign bodies, without cracking or breaking. Referring again to FIGURES 5 and 6, the bottom portion 106 has formed thereon a molded beaded portion 110 that reinforces the bottom edge of the shield while eliminating sharp contours. The bottom portion 106 further includes a pair of downwardly projecting tabs 112 that include a mounting aperture 114 that extends therethrough. The top portion of the face shield 100 includes a set of upwardly projecting mounting protrusions 116. The face shield can be mounted to various sport helmets by known retention mechanisms. For example, the face shield or protector 100 can be attached to a football helmet 120 by way of conventional securing and mounting straps and like retention elements, as shown in FIGURE 8. The shield 100 is secured to the face guard 122 of the helmet 120 by a set of T-bolts and nuts, and the top portion 104 of the shield 100 is wedged into the top of the face guard frame mounted directly to the helmet 120. When mounted on the helmet, the face shield 100 surrounds a substantial portion of the wearer's face, and particularly surrounds the nose and portions of the cheeks. More particularly, the shield surrounds the face such that the inside surface is substantially non-oblique relative to the wearer's face and the wearer's field of view is substantially normal to the inside surface of the lens portion 12 of the shield 10. The face shield also extends about the face in the horizontal direction a distance sufficient to include at least a substantial portion of the field of view of the wearer. FIGURE 7 illustrates a third embodiment of the face shield 200 of the present invention. The illustrated face shield 200 has a unitary lens portion 202 that has a top portion 204 and a bottom portion 206. The lens portion 202 also includes a horizontal curvature and a vertical curvature that exhibit the same properties as those described above in relation to the face shield 10 of FIGURES 1 and 2. The horizontal curvature of the face shield approximates a semi-circle and thus provides a wrap-around face shield that covers and protects the face of the wearer while providing a window portion that extends about a substantial portion of the wearer's field of view. This. wrap-around configuration of the lens 202 in both the horizontal and vertical directions provides a single view pane through which the wearer observes the external environment. This configuration allows the wearer to observe objects at any location through the lens portion 202 without requiring the wearer to change viewing environments, for example, view one object through the lens and another object at a different location outside of the view frame of the lens. According to one practice, the radius of the horizontal curvature of the face shield 202 is preferably between about 3 inches and about 5.5 inches, and most preferably is about 4 inches, and the radius of the vertical curvature is preferably in the range between about 6.5 inches and about 8.5 inches, and most preferably is about 7.4 inches. The foregoing radius dimensions represent the distance from an arbitrary center point to the arc defined by each curvature of the illustrated face shield 200. The illustrated face shield 100 also has a thickness dθ that is defined by outer and inner curved surfaces, as described above in relation to FIGURES 1-2 and 4. The illustrated face shield 200 preferably has an outer radius R1 that ranges between about 95 mm and about 110 mm, and most preferably is about 104 mm, and the radius R2 ranges between about 96 mm and about 105 mm, and most preferably is about 101 mm. For the vertical curvature of the lens 202, R1 preferably ranges between about 180 mm and 192 mm, and most preferably is about 188 mm, and R2 ranges between about 178 mm and about 186 mm, and most preferably is about 184 mm. The lens portion further has a pair of downwardly projecting portions 210 that extend below an intermediate portion 212 to form secondary lens portions. These portions preferably have a radius between about 1.0 inch and 2.0 inches. The illustrated face shield 200 has a height H1 defined at the intermediate portion 212 that ranges between 3.5 inches and about 4.1 inches. The height H2 of the lens portion other than at the intermediate portion varies about the length of the shield in the horizontal direction. The height H2 preferably varies between about 4 inches and about 5 inches, and preferably is about 4.25 inches. The optical and physical design properties described above in relation to shield 10 accrue to this embodiment to form an optically correct face shield that withstands the impact of foreign bodies, without cracking or breaking. Referring again to FIGURE 7, the bottom portion 206 has formed thereon a molded beaded portion 220 that reinforces the bottom edge of the shield while eliminating sharp contours. The beaded portion extends substantially about the entire periphery of the shield 200. The shield also includes ventilation apertures 240 formed in the top portion 234 of the bead. The ventilation apertures allow air to flow through the mask, either in an upward or downward direction, to provide for proper ventilation of the shield to resist fogging and aid clearing of the lens. The size and number of the ventilation apertures is not important to the teachings of the present invention. The face shield can be mounted to various sport helmets by known retention mechanisms. For example, the face shield 200 can be attached to a hockey helmet 250 by way of conventional pins, hooks, and securing and mounting straps, and like retention elements, as shown in FIGURE 9. When mounted on the helmet, the face shield 200 surrounds a substantial portion of the wearer's face, and particularly surrounds the nose and portions of the cheeks. More particularly, the shield surrounds the face such that the inside surface is substantially non-oblique relative to the wearer's face and the wearer's field of view is substantially normal to the inside surface of the lens portion 202 of the shield 200. The face shield also extends about the face in the horizontal direction a distance sufficient to include substantially the entire field of view of the wearer. The secondary lens portions 210 further project downwardly to ensure capture of a substantial portion of the downward field of view. The face shields of the invention shown and described above can be made from known processes and techniques, such as injection molding. The impact resistant face shield constructed according to the features of the present invention can be employed in a wide range of environments and for a wide range of uses. For example, the face shield shown and described above in relation to FIGURES 1-7 can be used by individuals for recreational and sporting activities in addition to football and hockey, such as skiing, roller-blading, soccer, basketball, baseball, lacrosse and other like activities. The face shield can also be employed in other industries by amateurs and/or professionals, such as by carpenters and medical personnel. It will thus be seen that the invention efficiently attains the objects set forth above, among those made apparent from the preceding description. Since certain changes may be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. It is also to be understood that the following claims are to cover all generic and specific features of the invention described herein, and all statements of the scope of the invention which, as a matter of language, might be said to fall therebetween. Having described the invention, what is claimed as new and desired to be secured by Letters Patent is: |
||||||
