SCREEN SAVER
A stack of laminated transparent lenses consists of two alternating optically clear materials in intimate contact. The materials are a plastic lens and clear adhesive. The adhesive is uninterrupted. The lens and the adhesive have refraction mismatch of less than 0.2. A tab portion is part of each lens acts as an aid in peeling away the outermost lens after contamination of the lens layer during racing conditions. The lens stack can be mounted to the posts on the face shield or laminated directly to a windshield.
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BACKGROUND OF THE INVENTION1. Field of the Invention
The present invention pertains to the following areas of technology: Apparel—Guards and Protectors; for wearer's head and face; eye shields such as goggles having a lens-cover plate; and windshield covers.
2. Description of the Prior Art
Face shields are employed in environments where contamination of the eyes may occur. It is well known in the art that flexible transparent lenses affixed by numerous methods are overlaid on the face shield for protection. The lenses are easily removed and discarded when visibility is reduced from the accumulation of dirt or other contaminants. In motor sports for instance, multiple layers of transparent lenses are overlaid on the face shield, each being sequentially removed as they become contaminated, because they reduce the visibility of the operator. The drawback of the lenses in the prior art is that each transparent lens applied over the face shield is itself a hindrance to good visibility due to its optical index of refraction. Most common materials used as plastics have optical indexes of refraction ranging from 1.47 to 1.498. The index mismatch between the removable lens and air (air has an optical index of 1.00) causes a reflection of 4% of the light that would normally come to the operator's eyes. This reflection effect is additive for each additional surface to air interface. Then for each removable lens having two surfaces, the reflections are 8%. Thus a stack of seven lenses would reflect 42% of the light away from the operator thereby reducing the brightness of the objects viewed. A second optical phenomenon occurs simultaneously that also reduces visibility. The reflections are bi-directional and thus make the lens stack appear as a semi-permeable mirror to the operator. This mirror effect further reduces visibility, because the light that passes through the lens stack reflects off of the operator's face and then reflects off of the lens stack into the operator's eyes. The effect to the operator is that he sees his own image on the inside of the stack nearly as brightly as the objects viewed on the outside. This significantly reduces visibility.
Another drawback to this stacking arrangement is that moisture exhaled by the operator's breath can cloud or fog-up the lenses also reducing visibility. The air spaces between each lens allows the moisture to enter this area.
SUMMARY OF THE INVENTIONAn object of the present invention is to provide a series of easily removable optically clear lens stacks that do not cause reflection to the operator's eyes. The prior art discloses reflective lens stacks that do cause reflections to the operator's eyes. An example of this type of prior art of reflective lens stacks is disclosed in U.S. Pat. No. 5,592,698 issued on Jan. 14, 1997 to Woods.
Refraction is the change in the direction in which waves travel when they pass from one kind of matter into another. Waves are refracted (bent) when they pass at an angle from one medium into another in which the velocity of light is different. The amount that a ray of a certain wavelength bends in passing from one medium to another is indicated by the index of refraction between the two mediums for that wavelength. The index of refraction indicates the amount that a light ray bends as it passes out of one substance and into another. When light passes from air to a denser substance, such as Mylar film, it slows down. If the light ray enters the Mylar film at any angle except a right angle, the slowing down causes the light ray to bend at the point of entry. This bending is called refraction. The ratio of the speed of light in air to its speed in the Mylar film is the Mylar film's index of refraction.
The present invention includes a series of alternating optically clear films whose indexes of refraction are matched to within 0.2 and which will nearly eliminate all reflections to the operator's eyes. The layers of film are adhesively laminated to one another and are compliant so there is no air between the layers. The film layers can be large and generally rectangular in shape with a tab extending from each of the film layers. The tabs can be staggered so that the user can remove the top most layer and then the next succeeding layer. This embodiment of the present invention can be applied to race car windshields, windows, visors or direct view displays such as ATM machines that are subject to contaminating environments. Accordingly, the present invention is an adhesively laminated multi-layered clear film adapted to be used on a racer's face shield, or on the windshield of a race car to keep the viewing area clean during the course of a race.
The present invention will now be discussed in detail. As stated above,
The adhesive material 20 will be a water-based acrylic optically clear adhesive or an oil based clear adhesive, with the water based adhesive being the preferred embodiment. After the seven layers are laminated or otherwise bonded together with the adhesive layers, the thickness of each adhesive layer is negligible even though the adhesive layers are illustrated in
The individual stackable lenses package, illustrated in
Referring back now to
The present invention as shown in the Drawing Figures has removal tab portions at both ends. This allows a right or left-handed person to easily remove the topmost layer. It also allows the driver to pull the tab with either hand depending on the circumstances of the race. It is to be understood that the present invention includes a laminated lenses with only a left tab portion 25, or only a right tab portion 35, or both a left and a right tab portion.
The windshield embodiment 100 illustrated in
The adhesive layer can be foreshortened so as to expose successively a portion of the lens layers without optical wetting to create a grasping tab.
The stack of removable lenses as illustrated in
The stack of removable lenses 100 can be applied to any type of optical window such as windshield, window, face shield, or a video display. It is common at an ATM terminal to have a video display for the customer. The surface of the display can be kept clear by using the present invention.
herein in what is conceived to be the best mode contemplated, it is recognized that departures may be made therefrom within the scope of the invention which is therefore not to be limited to the details disclosed herein, but is to be afforded the full scope of the invention.
Claims
1-32. (canceled)
33. A protective covering affixable to a video display comprising:
- a plurality of removable lenses adhesively affixed to one another and one of the plurality of removable lenses being affixed to the video display;
- each removable lens being held to each successive lens with a clear uninterrupted adhesive layer interposed between each successive removable lens;
- wherein a refraction mismatch between the plurality of superposed removable lenses and the adhesive layer is less than about 0.2 to mitigate reflections off of the lens.
34. The covering of claim 33 wherein the refraction mismatch between the lens and adhesive is less than about 0.12.
35. The covering of claim 33 wherein the adhesive layer is a water-based adhesive.
36. The covering of claim 33 wherein the adhesive layer is an oil based adhesive.
37. The covering of claim 33 wherein a distance between contact surfaces of each successive lenses is negligible.
38. The covering of claim 33 wherein the lens is fabricated from polyethylene terephalate, glass, vinyl, polypropelene or acrylic.
39. The covering of claim 33 further comprising an adhesive layer on a bottom surface of a lower most lens of the plurality of removable lenses, the adhesive layer on the bottom surface of the lower most lens of the plurality of removable lenses being adhered to the video display to mitigate reflections off of the video display and the lower most lens.
40. A protective covering for affixing to a video display, the protective covering comprising:
- a lens affixable to the video display with a clear uninterrupted adhesive layer interposed between the video display and the lens to mitigate reflections off of the video display and the lens, wherein a refraction mismatch between the lens and adhesive layer is less than about 0.2. to mitigate reflections off of the lens.
41. The protective covering of claim 40 wherein a refraction mismatch between the lens and adhesive layer is less than about 0.12.
42. The protective covering of claim 40 wherein the adhesive layer is a water-based adhesive.
43. The protective covering of claim 40 wherein the adhesive layer is an oil based adhesive.
44. The protective covering of claim 40 wherein a distance between the contact surfaces of each successive lenses is negligible.
45. The protective covering of claim 40 wherein the lens is fabricated from polyethylene terephalate, glass, vinyl, polypropelene or acrylic.
46. An apparatus comprising:
- an electronic device with a video display;
- a first lens affixed to the video display with a clear uninterrupted adhesive layer interposed between the video display and the first lens to mitigate reflections off of the video display and the lens, wherein a refraction mismatch between the first lens and adhesive layer is less than about 0.2. to mitigate reflections off of the first lens.
47. The apparatus of claim 46 wherein the clear uninterrupted adhesive layer for affixing the first lens to the video display is a water based adhesive.
48. The apparatus of claim 46 wherein the first lens is fabricated from polyethylene terephalate, glass, vinyl, polypropelene or acrylic.
49. The apparatus of claim 46 wherein a thickness of the first lens is about 0.5 mil to 7 mil.
50. The apparatus of claim 49 wherein a thickness of the adhesive layer is negligible.
51. The apparatus of claim 46 further comprising one or more second lenses affixed to each other and to the first lens, the one or more second lenses being removable from a lower second lens or the first lens.
52. The apparatus of claim 46 wherein the video display is fabricated from glass, and the clear uninterrupted adhesive layer contacts the glass to adhere the first lens to the video display.
53. The apparatus of claim 46 wherein the video display is fabricated from vinyl, and the clear uninterrupted adhesive layer contacts the vinyl to adhere the first lens to the video display.
54. The apparatus of claim 46 wherein the video display is fabricated from polypropylene, and the clear uninterrupted adhesive layer contacts the polypropylene to adhere the first lens to the video display.
55. The apparatus of claim 46 wherein the video display is fabricated from acrylic, and the clear uninterrupted adhesive layer contacts the acrylic to adhere the first lens to the video display.
56. A method for protecting a video display, the method comprising:
- providing the video display;
- providing a transparent lens having a clear uninterrupted adhesive layer disposed on one side of the lens;
- affixing the lens to the video display with the clear uninterrupted adhesive layer interposed between the video display and the lens, and a refraction mismatch between the lens and adhesive layer is less than about 0.2. to mitigate reflections off of the video display and the transparent lens.
57. The method of claim 56 wherein the providing the transparent lens step comprises the step of providing a plurality of removable lenses, each removable lens being held to each successive lens with a clear uninterrupted adhesive layer interposed between each successive removable lens wherein, the refraction mismatch between each successive removable lens and the adhesive layer is less than about 0.2 to mitigate reflections.
Type: Application
Filed: Apr 2, 2014
Publication Date: Aug 7, 2014
Applicant: Racing Optics, Inc. (Las Vegas, NV)
Inventors: Bart Wilson (Las Vegas, NV), Seth Wilson (Las Vegas, NV), Stephen S. Wilson (Las Vegas, NV)
Application Number: 14/243,731
International Classification: A42B 3/26 (20060101);