阅读说明：本技术 具有集成可成形模具的热成形挡风玻璃堆叠 (Thermoformed windshield stack with integrated formable mold ) 是由 斯蒂芬·S·威尔逊 巴特·E·威尔逊 于 2020-01-31 设计创作，主要内容包括：一种在弯曲基底上安装两个或更多透镜的堆叠的方法,包括：将可塑覆盖物置于弯曲基底上,可塑覆盖物包括具有两个或更多透镜的堆叠、介于两个或更多透镜中每对相邻透镜之间的粘合剂层、以及设置在堆叠的最外透镜上的5个牺牲层,该牺牲层包括牺牲透镜和介于牺牲透镜与堆叠的最外透镜之间的牺牲粘合剂。该方法可以包括向牺牲层施加热量和压力,以及剥离牺牲层以露出两个或更多透镜的堆叠。(A method of mounting a stack of two or more lenses on a curved substrate, comprising: a moldable covering is placed on the curved substrate, the moldable covering comprising a stack of two or more lenses, an adhesive layer between each pair of adjacent lenses of the two or more lenses, and 5 sacrificial layers disposed on outermost lenses of the stack, the sacrificial layers comprising sacrificial lenses and a sacrificial adhesive between the sacrificial lenses and the outermost lenses of the stack. The method may include applying heat and pressure to the sacrificial layer, and stripping the sacrificial layer to expose the stack of two or more lenses.)

1. A method of mounting a stack of two or more lenses on a curved substrate, the method comprising:

placing a moldable covering on a curved substrate, the moldable covering comprising a stack of two or more lenses, an adhesive layer between each pair of adjacent lenses of the two or more lenses, and a sacrificial layer disposed on an outermost lens of the stack, the sacrificial layer comprising a sacrificial lens and a sacrificial adhesive between the sacrificial lens and the outermost lens of the stack;

applying heat and pressure to the sacrificial layer; and

the sacrificial layer is stripped to expose the stack of two or more lenses.

2. The method of claim 1, wherein the curved substrate is a composite curved substrate.

3. The method of claim 2, wherein the curved substrate is a windshield.

4. The method of claim 1, wherein the sacrificial layer is more heat resistant than an outermost lens of the stack.

5. The method of claim 4, wherein the sacrificial layer is less scratch resistant than an outermost lens of the stack.

6. The method of claim 1, wherein the sacrificial layer is less scratch resistant than an outermost lens of the stack.

7. The method of claim 1, wherein the sacrificial lens comprises a biaxially oriented polyethylene terephthalate film.

8. The method of claim 7, wherein the biaxially oriented polyethylene terephthalate film is capable of withstanding temperatures from room temperature to 220 ℃ for two hours.

9. The method of claim 1, wherein the sacrificial lens comprises an opaque polyester film.

10. The method of claim 9, wherein the outermost lens of the stack comprises a transparent polyethylene terephthalate film.

11. A moldable covering securable to a curved substrate, the moldable covering comprising:

a stack having two or more lenses;

an adhesive layer interposed between each pair of adjacent lenses of the two or more lenses;

a sacrificial layer disposed on the outermost lens of the stack, the sacrificial layer comprising a sacrificial lens and a sacrificial adhesive between the sacrificial lens and the outermost lens of the stack, the sacrificial layer being more heat resistant than the outermost lens of the stack.

12. The moldable covering of claim 11, wherein the sacrificial lens comprises a biaxially oriented polyethylene terephthalate film.

13. The plastic covering of claim 12, wherein the biaxially oriented polyethylene terephthalate film is capable of withstanding temperatures from room temperature to 220 ℃ for two hours.

14. The moldable covering of claim 11, wherein the sacrificial lens comprises an opaque polyester film.

15. The moldable covering of claim 14, wherein the outermost lens of the stack comprises a transparent polyethylene terephthalate film.

16. A moldable covering securable to a curved substrate, the moldable covering comprising:

a stack having two or more lenses;

an adhesive layer interposed between each pair of adjacent lenses of the two or more lenses;

a sacrificial layer disposed on the outermost lens of the stack, the sacrificial layer comprising a sacrificial lens and a sacrificial adhesive between the sacrificial lens and the outermost lens of the stack, the sacrificial layer being less scratch resistant than the outermost lens of the stack.

17. The moldable covering of claim 16, wherein the sacrificial lens comprises a biaxially oriented polyethylene terephthalate film.

18. The plastic covering of claim 17, wherein the biaxially oriented polyethylene terephthalate film is capable of withstanding temperatures from room temperature to 220 ℃ for two hours.

19. The moldable covering of claim 16, wherein the sacrificial lens comprises an opaque polyester film.

20. The moldable covering of claim 19, wherein the outermost lens of the stack comprises a transparent polyethylene terephthalate film.

Technical Field

The present disclosure relates generally to transparent covers for windows and, more particularly, to a transparent cover having a plurality of lenses stacked one on top of the other and bonded together by an adhesive.

Background

Securing a transparent lens to a curved substrate such as a windshield (also referred to as a windshield) can have a number of benefits. Such a covering may provide the following protection: pitting and cracking prevention, coloration (e.g., for privacy), thermal insulation, Ultraviolet (UV) radiation blocking, and/or decoration. Such a stack of transparent lenses can be easily torn off when the outermost lens becomes dirty and obstructs the view of the driver, as may occur, for example, in an off-road vehicle.

Although the surface of a typical windshield typically exhibits multidirectional curvature, the transparent lens itself may be flat (as in the case of a polyethylene terephthalate (PET) film manufactured in a roll-to-roll process). To mount a flat film to a compound curve windshield surface, for example, the film may be overmolded on the windshield by laying the film on the windshield and applying heat to the uppermost surface to shrink or stretch the film to assume the shape of the windshield. However, this process may result in uneven or excessive heating, which may cause optical distortion of the film and may create areas where the film is not sufficiently bonded to the windshield. In addition, installers attempt to apply pressure to the film with a card or spatula, which may result in permanently scratching the visible surface during installation.

Disclosure of Invention

The present disclosure contemplates various systems and methods for overcoming the shortcomings of the related art described above. One aspect of an embodiment of the present disclosure is a method of mounting a stack of two or more lenses on a curved substrate. The method can include placing a moldable covering on the curved substrate, the moldable covering comprising a stack having two or more lenses, an adhesive layer between each pair of adjacent lenses of the two or more lenses, and a sacrificial layer disposed on an outermost lens of the stack, the sacrificial layer comprising a sacrificial lens and a sacrificial adhesive between the sacrificial lens and the outermost lens of the stack. The method may include applying heat and pressure to the sacrificial layer, and stripping the sacrificial layer to expose the stack of two or more lenses.

The curved substrate may be a composite curved substrate. The curved substrate may be a windshield.

The sacrificial layer may be more heat resistant than the outermost lens of the stack.

The sacrificial layer may be less scratch resistant than the outermost lens of the stack.

The sacrificial lens may comprise a biaxially oriented polyethylene terephthalate film. Biaxially oriented polyethylene terephthalate films can withstand temperatures from room temperature to 220 ℃ for two hours.

The sacrificial lens may comprise an opaque polyester film. The outermost lens of the stack may comprise a transparent polyethylene terephthalate film.

Another aspect of an embodiment of the present disclosure is a moldable covering securable to a curved substrate, the moldable covering may include a stack having two or more lenses, an adhesive layer interposed between each pair of adjacent lenses of the two or more lenses, and a sacrificial layer disposed on an outermost lens of the stack, the sacrificial layer including a sacrificial lens and a sacrificial adhesive interposed between the sacrificial lens and the outermost lens of the stack, the sacrificial layer being more heat resistant than the outermost lens of the stack.

The sacrificial lens may comprise a biaxially oriented polyethylene terephthalate film. Biaxially oriented polyethylene terephthalate films can withstand temperatures from room temperature to 220 ℃ for two hours.

The sacrificial lens may comprise an opaque polyester film. The outermost lens of the stack may comprise a transparent polyethylene terephthalate film.

Yet another aspect of an embodiment of the present disclosure is a moldable covering that can be secured to a curved substrate. The moldable covering may include a stack having two or more lenses, an adhesive layer between each pair of adjacent lenses of the two or more lenses, and a sacrificial layer disposed on an outermost lens of the stack, the sacrificial layer including a sacrificial lens and a sacrificial adhesive between the sacrificial lens and the outermost lens of the stack, the sacrificial layer being less scratch resistant than the outermost lens of the stack.

The sacrificial lens may comprise a biaxially oriented polyethylene terephthalate film. Biaxially oriented polyethylene terephthalate films can withstand temperatures from room temperature to 220 ℃ for two hours.

The sacrificial lens may comprise an opaque polyester film. The outermost lens of the stack may comprise a transparent polyethylene terephthalate film.

Drawings

The above and other features and advantages of the embodiments disclosed herein will be better understood by reference to the following description and drawings, in which like numbers refer to like parts throughout, and in which:

fig. 1 is a schematic side view of a moldable covering in accordance with an embodiment of the present disclosure;

FIG. 2 shows the moldable covering placed over the windshield at the beginning of the process of applying heat and pressure to the sacrificial layer of the moldable covering;

FIG. 3 shows a moldable covering on a windshield at the end of the process of applying heat and pressure;

FIG. 4 shows the malleable covering on the windshield as the sacrificial layer is peeled away to expose the stack of transparent lenses;

FIG. 5 shows the stack of transparent lenses after being trimmed to fit the windshield; and

fig. 6 illustrates an exemplary operational procedure according to an embodiment of the present disclosure.

Detailed Description

The present disclosure includes various embodiments of a moldable covering having a stack of two or more lenses and methods of mounting the same. The detailed description set forth below in connection with the appended drawings is intended as a description of several presently contemplated embodiments and is not intended to represent the only forms in which the disclosed invention may be developed or utilized. The description sets forth the functions and features in connection with the described embodiments. However, it is to be understood that the same or equivalent functions may be accomplished by other embodiments that are also intended to be encompassed within the scope of the disclosure. It is further understood that relational terms such as first and second, and the like, may be used solely to distinguish one entity from another entity without necessarily requiring or implying any actual such relationship or order between such entities.

Fig. 1 is a schematic side view of a moldable covering 100 in accordance with an embodiment of the present disclosure. The pliable cover 100 may be affixed to a curved substrate 10, such as a windshield, as part of the process of installing the stack with lenses 110a, 110 b. The mounted stack of lenses 110 may provide protection, coloration, thermal insulation, Ultraviolet (UV) radiation blocking, decoration to the substrate 10, and/or the ability to peel off and discard the outermost layer 110n (and thereafter newly expose any layers 110) as desired during the lifetime of the article. In addition to the lenses 110, the moldable covering 100 may include adhesive layers 120a, 120b,. 120n (collectively, adhesive layers 120) disposed on each lens 110, respectively, such that the adhesive layers 120 are interposed between each pair of adjacent lenses 110 of the stack. On the outermost lens 110n of the lens 110 stack, a sacrificial layer 130 may be provided, enabling an improved process of mounting the lens 110 stack to the substrate 10. The sacrificial layer 130 may include a sacrificial lens 132 and a sacrificial adhesive 134 between the sacrificial lens 132 and the outermost lens 110n of the lens 110 stack. When the lens 110 stack is mounted, heat and pressure may be applied to the sacrificial layer 130 to adapt the lens 110 stack to the shape of the curved substrate 10. Thereafter, the sacrificial layer 130 can be peeled away to expose the final article 140 including the mounted lens 110.

When the lens 110 is overmolded on the curved substrate 10 without the sacrificial layer 130, this process may result in uneven or excessive heating as described above, and may permanently scratch the outermost lens 110n with a card or a spatula. The inventors have found that these problems arise primarily from the lack of pressure exerted by the concave mold cavity when the lens 110 stack conforms to the convex surface represented by the curved substrate 10. As a result, when an installer attempts to mold the lens 110 stack to the curved substrate 10, neither of the heat nor the pressure is uniformly distributed, causing the problem. By providing the sacrificial layer 130 as a missing mold cavity, the disclosed moldable covering 100 can overcome these deficiencies in at least two ways. First, the sacrificial layer 130 may allow an installer to apply heat and pressure without fear of scratching or otherwise damaging the final article. The sacrificial layer 130, along with any surface damage, may simply be discarded, while the outermost lens 110n of the underlying lens 110 stack remains pristine. Second, when heat and pressure are applied to the lens 110 stack through the intervening sacrificial layer 130, the sacrificial layer 130 may serve to distribute the heat and pressure over a larger area, enabling the heat and pressure to be applied more uniformly as the sacrificial layer 130 and the underlying lens 110 stack together conform to the shape of the curved substrate 10.

The lens 110 may comprise a transparent polyethylene terephthalate (PET) film, such as biaxially oriented polyethylene terephthalate (BoPET), and may be made from a sheet of polyester film sold by DuPont under the registered trademark Mylar. The thickness of each lens 110 may be between 0.5 mil and 7 mil (1 mil is 0.001"), such as 2 mils. Even after the adhesive material of the adhesive layer 120 is applied to the 2 mil thick lens 110, the combined thickness of the 2 mil thick lens 110 and the adhesive layer 120 may still be 2 mils because the adhesive layer 120 has only a nominal thickness.

The adhesive for the adhesive layer 120 may be applied, for example, to selected areas about the perimeter of the plastic cover 100 as described in U.S. patent No.6,536,045 to Wilson, entitled "Tear-off Optical Stack viewing personal Mount," issued on 25/3/2003, the entire contents of which are expressly incorporated herein by reference. The adhesive layer 120 may be made of an optically clear, low tack material, and may include a water-based acrylic optically clear adhesive or an oil-based clear adhesive. The adhesive layer 120a used to secure the moldable covering 100 to the substrate 10 may be the same as or different (e.g., stronger) than the adhesive layers 120b,.. 120n, etc. between each pair of adjacent lenses 110 in the stack. For example, a stronger adhesive may be used during use without removing the entire lens 110 stack from the substrate 10 and tearing off the individual lenses 110. Along the same lines, the adhesive for the adhesive layers 120b,. 120n between each pair of adjacent lenses 110 can be stronger than the sacrificial adhesive 134 for the sacrificial layer 130, so that the sacrificial layer 130 can be torn away without removing the outermost lens 110n from the stack of lenses 110. The sacrificial adhesive 134 may similarly be a low tack material, and may comprise a water-based acrylic optically clear adhesive or an oil-based clear adhesive. However, in the case of having a sacrificial adhesive 134, an opaque adhesive may also be substituted as the sacrificial adhesive 134 is removed in the final article 140.

The scratch resistance of the lens 110 and/or the blocking (absorption or reflection) of UV radiation may be optimized. For example, the outer side of each lens 110 may be coated by depositing, spraying, laminating, or otherwise applying a coating (e.g., a silicone acrylate oligomer and/or an acrylated polyurethane polyol) that optimizes scratch resistance and/or UV radiation blocking properties as desired for properties suitable for the final article 140. These properties can be relaxed in the fabrication of the sacrificial layer 130, since the sacrificial layer 130 will not be present after the mounting is complete. Thus, for example, the sacrificial layer 130 may be less scratch resistant than the outermost lens 120n of the lens 120 stack. At the same time, the heat resistance of the sacrificial layer 130 can be optimized, for example, by applying a coating having superior heat resistance (e.g., a silicone acrylate oligomer and/or an acrylated polyurethane polyol), because this can directly heat the sacrificial layer 130 as part of thermoforming the moldable covering 100 into the shape of the curved substrate 10. This heat resistance may be relaxed in the underlying lens 100 stack, as these lenses may be heated only indirectly through the sacrificial layer 130. Thus, for example, the sacrificial layer 130 may be more heat resistant than the outermost lens 110n of the lens 100 stack.

The sacrificial layer 130 may be made of high temperature PET, for example, PET that can withstand temperatures from room temperature to 220 ℃ for two hours (e.g., without degradation). The high temperature PET may be a clear BoPET, capable of viewing the stack of lenses 110 located thereunder during the molding process, and may be, for example, a Polyester Film sold under the trade name Hostaphan RBB by Mitsubishi Polyester Film Group. Such high temperature BoPET may be preferred when using hot air to heat the sacrificial layer 130 during molding. Alternatively, the sacrificial layer 130 may be made of an opaque (e.g., white) Polyester Film, such as that sold under the trade name Hostaphan WIN by Mitsubishi Polyester Film Group. Such an opaque polyester film may provide increased thermal uniformity when the sacrificial layer 130 is heated using an infrared heater during molding.

While the sacrificial layer 130 (e.g., sacrificial lens 132 and/or sacrificial adhesive 134) may be optimized to withstand the heat of the mounting process and evenly distribute the heat and pressure to the underlying lens 110 stack, the sacrificial layer 130 generally does not have to meet the more stringent performance criteria of the underlying lens 110 stack. For example, the lens stack may be designed to meet federal standards for visible light transmission (e.g., 70%), such as set forth in American National Standards Institute (ANSI) standards Z26.1-1966 and Z26.la-1969, as well as scratch resistance (e.g., by windshield wipers) and/or to absorb or reflect UV light, as described above, to protect the lens 110 from sunlight. By relaxing these requirements on the sacrificial layer 130, while providing a more robust surface for the application of heat and pressure without concern during mounting, the compliant cover 100 enables the lens 110 stack to be mounted in a more efficient way. With the sacrificial layer 130 as a cavity, the layers with the lens 110 and adhesive 120 are better retained, shaped and cured with the curved substrate 10 and are not scratched during the mounting process.

Fig. 2 shows the moldable covering 100 placed on an automotive windshield 20 as the substrate 10 at the beginning of the process of applying heat and pressure to the sacrificial layer 130 of the moldable covering 100. The plastic cover 100 may be adhered to a windshield by a dry-applied Adhesive 120a (see fig. 1), as described in U.S. patent No.9,295,297 to Wilson, entitled "Adhesive movable Stack of Removable Layers," published on 29/3/2016, the entire contents of which are expressly incorporated herein by reference. Alternatively, the wet-applied adhesive 120a may be used as described in U.S. patent No.9,128,545 to Wilson, entitled "Touch Screen Shield", published on 8.9.2015, which is expressly incorporated herein by reference in its entirety. Because the pliable cover 100 may be flat (e.g., manufactured by a roll-to-roll process), the pliable cover 100 may initially not conform to the curved shape of the windshield, thereby forming larger or smaller areas of adhesion and air pockets/bubbles between the pliable cover 100 and the windshield. Thus, to conform the moldable covering 100 to the shape of the windshield, heat and pressure may be applied using a heater 30 such as a hot air source (e.g., a heat gun or blow dryer) or an infrared heater. At the same time, a card or spatula may be used to apply pressure to the moldable covering 100. When the installer heats and presses down on the sacrificial layer 130 of the moldable covering 100, the sacrificial layer 130 can contract and stretch to assume a profile corresponding to the curved substrate 10 (windshield) with the lens 110 stack between the sacrificial layer and the curved substrate. In this way, the sacrificial layer 130 may act as a cavity to thermoform the underlying stack of lenses 110 into the shape of the windshield, evenly distribute heat and pressure to shrink and stretch the lenses 110 into the correct shape, and cure the adhesive layer 120.

Fig. 3 shows the moldable covering 100 on the windshield at the end of the process of applying heat and pressure. At this stage, the moldable covering 100, including the sacrificial layer 130 and the underlying lens 110, is molded into the curved shape of the windshield without air pockets/bubbles. The upper surface of the sacrificial layer 130 may have various scratches and other imperfections caused by the installer applying pressure to the moldable covering 100 using a spatula or card. However, the lens 110 located thereunder is not contacted because it is protected by the sacrificial layer 130.

Fig. 4 shows the moldable covering 100 on the windshield when the sacrificial layer 130 is peeled away to expose the transparent lens 110 stack. Remaining on the windshield is the final article 140 (see fig. 1) comprising the stack of lenses 110 and the adhesive layer 120. The final article 140 may meet performance standards as described above, including federal standards for visible light transmission (e.g., 70%) and scratch resistance and/or UV absorption or blocking. The lenses 110 of the final article 140 may conform precisely to the shape of the windshield and may be free of imperfections even on the outermost lenses 110 n. Only the stripped sacrificial layer 130 may be discarded.

Fig. 5 shows a final article 140 comprising a stack of transparent lenses 110 after trimming the stack of transparent lenses 110 to fit into a windshield of substrate 10. The transparent lens 110 stack may be trimmed using a knife such as an art knife or a box opener with a stainless steel blade (a carbon blade may damage the windshield). As shown in fig. 5, trimming may be performed after the sacrificial layer 130 has been removed from the moldable cap 100, such that only the exposed final article 140 is trimmed. Alternatively, as shown in fig. 3, once the moldable covering 100 has conformed to the shape of the windshield, it may be trimmed prior to removing the sacrificial layer 130. In either case, the finished final article 140 may effectively be invisible because the finished final article 140 matches the shape of the underlying windshield (although the finished final article may change the color of the windshield as in the case of window tinting).

Fig. 6 illustrates an exemplary operational procedure according to an embodiment of the present disclosure. The operational flow of fig. 6 may be provided as an exemplary method of installing a final article 140 comprising a stack of lenses 110 as shown in fig. 1. First, the moldable covering 100 including both the final article 140 and the sacrificial layer 130 can be placed on a curved substrate 10 such as the windshield of the automobile 20 shown in fig. 2 with the adhesive layer 120a on the windshield and the sacrificial layer 130 facing away from the windshield (step 610). For easier installation, the moldable covering 100 may be rough cut (e.g., using an electric film cutter) so as not to extend too far out of the windshield. The operational flow may continue, as described in connection with fig. 2 and 3, with applying heat and pressure to the sacrificial layer 130 of the moldable covering 100 to thermoform the moldable covering 100 into the curved shape of the windshield (step 620). After cooling the moldable covering 100, the operational flow may end with stripping the sacrificial layer 130 to expose the final article 140 as described in connection with fig. 4 (step 630) and performing the final trimming as described in connection with fig. 5 (step 640). As described above, steps 630 and 640 may be performed in the order shown in FIG. 6 or in reverse order. To this end, the final article 140 comprising the stack of lenses 110 is uniformly formed and affixed to the windshield surface.

Three lenses 110 are shown in the example of fig. 1. However, it is contemplated that the moldable covering 100 may include a stack of four or more lenses 110, or a stack of two lenses 110, or even a single lens 110, with the number of lenses 110 depending on the particular application. Contrary to convention, the inventors have found that stacks with multiple lenses 110 are easier to thermoform to a curved substrate 10 than stacks with a single lens 110.

Throughout this disclosure, the word "transparent" is used broadly to encompass any material through which it may be viewed. The word "transparent" does not exclude translucent, hazy, frosted, colored or tinted materials.

The coatings described throughout this disclosure may be applied according to known methods such as spin coating, dip coating, or vacuum deposition.

The above description is given by way of example and not limitation. Those skilled in the art, having the benefit of this disclosure, may devise variations that are within the scope and spirit of the invention disclosed herein. Furthermore, various features of the embodiments disclosed herein can be used alone, or in combination with one another, and are not intended to be limited to the specific combinations described herein. Thus, the scope of the claims is not limited by the illustrated embodiments.