RU2680646C2 - Interior/exterior moving designs - Google Patents

Abstract

FIELD: lighting.

SUBSTANCE: group of inventions relates to vehicle illumination systems. Illumination apparatus for a vehicle comprises a vehicle panel and a first light source disposed proximate to and separate from the vehicle panel. Vehicle panel has a first photoluminescent portion and a second photoluminescent portion. First photoluminescent portion comprises a first luminescent absorption range configured to generate a first output color. Second photoluminescent portion comprises a second luminescent absorption range configured to generate a second output color. First photoluminescent portion overlaps the second photoluminescent portion forming an overlapping portion. First source is configured to emit a first emission at a first wavelength. First wavelength is within the first absorption range and outside the second absorption range.

EFFECT: improved ambient and work light quality.

17 cl, 7 dwg

Description

Cross references to related applications

[0001] This application is a partial continuation of US patent application No. 14 / 301,635, filed June 11, 2014 and entitled "PHOTOLUMINISCENT VEHICLE READING LAMP", which is a partial continuation of US patent application No. 14 / 156,869, filed January 16, 2014, entitled " VEHICLE DOME LIGHTING SYSTEM WITH PHOTOLUMINESCENT STRUCTURE ", which is a partial continuation of US patent application No. 14 / 086,442, filed November 21, 2013 and entitled" VEHICLE LIGHTING SYSTEM WITH PHOTOLUMINESCENT STRUCTURE ". The aforementioned related applications are incorporated herein by reference in their entirety.

FIELD OF THE INVENTION

[0002] The present invention generally relates to vehicle lighting systems, and more particularly, to vehicle lighting systems using photoluminescent structures.

State of the art

[0003] Lighting arising from photoluminescent materials offers a unique and eye-catching visual experience. Therefore, it is desirable to incorporate such photoluminescent materials into vehicle fragments in order to provide ambient and working lighting.

SUMMARY OF THE INVENTION

[0004] According to one aspect of the present invention, a lighting device for a vehicle is disclosed. The lighting device comprises at least one vehicle panel having a first photoluminescent fragment and a second photoluminescent fragment. The first photoluminescent fragment has a first luminescent absorption range, and the second photoluminescent fragment has a second luminescent absorption range. The lighting device further comprises a first light source configured to emit a first radiation with a first wavelength, wherein the first wavelength is in the first absorption range and outside of the second absorption range.

[0005] According to another aspect of the present invention, a lighting system for a vehicle is disclosed. The lighting system comprises a light source configured to emit a first radiation. The lighting system further comprises a panel close to the light source having a polymer coating located on it. The polymer coating contains a photoluminescent fragment extending longitudinally along the surface of the panel. The first radiation is emitted almost parallel to the surface, so that the polymer coating emits a second radiation.

[0006] According to another aspect of the present invention, a lighting system for a vehicle is disclosed. The lighting system comprises a controller in conjunction with a light source configured to emit a first radiation having a first wavelength. The photoluminescent fragment extends longitudinally along the surface of the panel close to the light source. The photoluminescent fragment is configured to emit a second radiation in response to receiving the first radiation, while the controller is configured to selectively illuminate a plurality of sections of the photoluminescent fragment.

[0007] These and other aspects, objects, and features of the present invention will be understood and appreciated by those skilled in the art upon examination of the following description, claims, and accompanying drawings.

Brief Description of the Drawings

[0008] In the drawings:

[0009] FIG. 1 is a perspective view of a vehicle containing a lighting system configured to create a motion effect;

[0010] FIG. 2A illustrates a photoluminescent structure presented as a coating;

[0011] FIG. 2B illustrates a photoluminescent structure represented as a discrete particle;

[0012] FIG. 2C illustrates the many photoluminescent structures represented as discrete particles and embedded in a separate structure;

[0013] FIG. 3 illustrates a vehicle lighting system configured to convert a first light emission into a second light emission;

[0014] FIG. 4 illustrates a lighting system configured to convert first and second light emissions into third and fourth light emissions, respectively;

[0015] FIG. 5 is a graphical representation showing a plurality of Stokes shifts corresponding to the conversion of the first and second light emission into the third and fourth light emission;

[0016] FIG. 6A is a detailed view of a first light emission configured to illuminate a first photoluminescent fragment of a vehicle;

[0017] FIG. 6B is a detailed view of a second light emission configured to illuminate a second photoluminescent fragment of a vehicle;

[0018] FIG. 6C is a detailed view of a first and second light emission configured to illuminate a first and second photoluminescent vehicle fragments;

[0019] FIG. 7A is a detailed view of a first photoluminescent fragment and a second photoluminescent fragment, configured to illuminate a vehicle surface; and

[0020] FIG. 7B is a detailed view of a first photoluminescent fragment and a second photoluminescent fragment, configured to illuminate a vehicle surface in accordance with the invention.

The implementation of the invention

[0021] As required, detailed embodiments of the present invention are disclosed herein. However, it should be understood that the disclosed embodiments are merely examples of the invention, which may be embodied in various and alternative forms. Drawings are not required for detailed design, and some schemes may be exaggerated or minimized to show an overview of functions. Therefore, the specific structural and functional details disclosed in this document should not be interpreted as limiting, but simply as representing the basis for study by a person skilled in the art in order to apply the present invention in different ways.

[0022] As used herein, the term “and / or” when used in a list of two or more elements means that any one of the listed elements can be applied on its own, or any combination of two or more of the listed elements can to be applied. For example, if a composition is described as containing components A, B and / or C, the composition may contain only A; only B; only C; A and B in combination; A and C in combination; B and C in combination; or A, B and C in combination.

[0023] The following disclosure describes a lighting system for a vehicle configured to illuminate a first photoluminescent fragment of at least one panel of a vehicle having a first luminescent absorption range. The first light source is configured to emit a first light emission having a first wavelength corresponding to a first luminescent absorption range. In response to receiving the first radiation, the first photoluminescent fragment is configured to emit a second radiation. The second radiation has a second wavelength, which differs from the first wavelength in that the second wavelength is longer and more sharply visible to the human eye. In this configuration, the lighting system provides illumination of the first photoluminescent fragment from the first light source.

[0024] In some implementations, the lighting system further includes a second light source and a second photoluminescent fragment having a second luminescent absorption range. The second light source is configured to emit a third radiation having a third wavelength corresponding to the second photoluminescent fragment. In response to receiving the third radiation, the second photoluminescent fragment is configured to emit the fourth radiation. The lighting system functions to create a perceived motion effect or animation by selectively lighting the first light source and the second light source to form second and fourth illumination from the first and second photoluminescent fragments, respectively.

[0025] A motion effect or animation, as discussed herein, refers to a perceived visual effect that may result, at least in part, from the inertia of a motion phenomenon. For example, when the first and second light sources alternately emit the first and third light emission, the first and second photoluminescent fragments can be selectively illuminated and emit the second and fourth light emissions. Alternating between the output of the second and fourth light emissions, the lighting system functions to create a motion effect corresponding to the spatial relationship between the first and second photoluminescent fragments. The motion effect may correspond to a flicker, wobble and / or animated sequence configured to create a moving pattern and / or graphics on a vehicle.

[0026] Referring to FIG. 1, a perspective view of a vehicle 10 is shown, comprising a lighting system 12 configured to create a motion effect. The lighting system 12 includes at least one light source 14 configured to emit a first radiation 16 having a first wavelength. The lighting system 12 further comprises at least one photoluminescent fragment 18, configured to emit a second radiation 20 having a second wavelength. The second radiation 20 causes the at least one photoluminescent fragment 18 to have an ambient light having a color corresponding to one or more wavelengths corresponding to the second wavelength. At least one photoluminescent fragment 18 may contain at least one photoluminescent structure, which is excited in response to receiving the first radiation 16 and converts the first wavelength into a second wavelength to illuminate at least one photoluminescent fragment 18.

[0027] At least one photoluminescent fragment 18 may correspond to a plurality of photoluminescent fragments. Similarly, at least one light source 14 may correspond to a plurality of light sources. In some implementations, each of the plurality of light sources is configured to correspond to each of the photoluminescent fragments in order to illuminate the corresponding photoluminescent fragment. For example, the first light source 22 may correspond to the first photoluminescent fragment 24. The first light source 22 may be configured to emit the first radiation 16, so that the photoluminescent fragment 24 becomes excited and converts the first radiation 16 to the second radiation 20 having a second wavelength.

[0028] In some implementations, the second light source 26 may be configured to emit a third radiation 28 corresponding to the second photoluminescent fragment 30. The second light source 26 may correspond to one of the plurality of light sources shown in FIG. 1, as at least one light source 14. The second photoluminescent fragment 30 may correspond to one of the plurality of photoluminescent fragments shown in FIG. 1 as at least one photoluminescent fragment 18. In some implementations, the second photoluminescent fragment 30 may be configured to have a shape or image that complements the first photoluminescent fragment 24, for example, a shadow, an accent, and / or some shape configured to form a blur or motion effect displaced relative to the first photoluminescent fragment 24.

[0029] In order to create a motion effect or accent, the second photoluminescent fragment 30 is configured to become excited and convert the third radiation 28 into a fourth radiation 32 having a fourth wavelength. Thus, the invention provides a lighting system 12 that must function to selectively illuminate the first photoluminescent fragment 24 and the second photoluminescent fragment 30 to create an effect of animated movement. The second light source 26 and the second photoluminescent fragment 30 may be located on the vehicle 10 similarly to at least one light source 14 and at least one photoluminescent fragment 18, respectively. Further discussion of the plurality of light sources and photoluminescent fragments is discussed herein, in particular with reference to FIG. 6A-7B.

[0030] Referring to FIG. 2A-2C, the photoluminescent structure 42 is generally shown as a coating (e.g., a film) that can be applied to a vehicle part, a separate particle that can be embedded in a vehicle part, and many individual particles embedded in a separate structure, which can be applied to the vehicle part, respectively. The photoluminescent structure 42 may correspond to the photoluminescent fragments that are discussed in this document, for example, the first photoluminescent fragment 24 and the second photoluminescent fragment 30. At the most basic level, the photoluminescent structure 42 includes an energy conversion layer 44, which can be represented as a single layer or multilayer structure as shown by broken lines in FIG. 2A and 2B.

[0031] The energy conversion layer 44 may include one or more photoluminescent materials having energy conversion elements selected from a phosphorescent or fluorescent material. Photoluminescent materials can be created to convert the input electromagnetic radiation to the output electromagnetic radiation, in General, having a longer wavelength and expressing a color that is not characteristic of the input electromagnetic radiation. The difference in wavelength between the input and output electromagnetic radiation is called the Stokes shift and serves as the principle of the excitation mechanism for the energy conversion process corresponding to a change in the wavelength of light, often called down-conversion. In the various implementations discussed herein, each of the light wavelengths (e.g., the first wavelength, etc.) corresponds to the electromagnetic radiation used in the conversion process.

[0032] Each of the photoluminescent fragments may contain at least one photoluminescent structure 42 containing an energy conversion layer (eg, a conversion layer 44). The energy conversion layer 44 may be prepared by dispersing the photoluminescent material in the polymer matrix 50 to form a uniform mixture using a variety of methods. Such methods may include preparing an energy conversion layer 44 from the composition in a liquid carrier substance and applying the energy conversion layer 44 to a desired flat and / or non-planar substrate of the vehicle part. The coating of the energy conversion layer 44 can be applied to a vehicle part by painting, screen printing, spraying, crevice spraying, dipping, roller coating and coating with the removal of excess using a strip. Additionally, the energy conversion layer 44 may be prepared by methods that do not use a liquid carrier substance.

[0033] For example, a solid state composition (a homogeneous dry mixture) of one or more photoluminescent materials may be included in the polymer matrix 50 to provide an energy conversion layer 44. The polymer matrix 50 may be formed by extrusion, injection molding, compression molding, extrusion, hot molding, etc. In cases where one or more energy conversion layers 44 are represented as particles, single or multilayer energy conversion layers 44 may be incorporated into a vehicle part or panel. When the energy conversion layer 44 includes a multilayer composition, each layer can be sequentially applied. Additionally, the layers can be separately prepared and later layered or extruded together to form a solid layer. The layers can also be coextruded to prepare an integrated multilayer energy conversion structure.

[0034] Referring back to FIG. 2A and 2B, the photoluminescent structure 42 may optionally include at least one stabilizing layer 46 to protect the photoluminescent material contained in the energy conversion layer 44 from photolytic and thermal wear. The stabilizing layer 46 may be configured as a separate layer optically coupled and adhered to the energy conversion layer 44. The stabilizing layer 46 may also be combined with the energy conversion layer 44. The photoluminescent structure 42 may also optionally include a protective layer 48 optically bonded and adhered to the stabilizing layer 46 or any other layer or coating to protect the photoluminescent structure 42 from physical and chemical damage caused by environmental influences.

[0035] The stabilizing layer 46 and / or the protective layer 48 may be combined with the energy conversion layer 44 to form a combined photoluminescent structure 42 by sequentially applying or printing each layer or by sequentially layering or stamping the pattern. Alternatively, several layers can be combined by sequential application, layering or extrusion to form a substructure. The substructure may then be layered or extruded to form the integrated photoluminescent structure 42. Once formed, the photoluminescent structure 42 can be applied to a selected vehicle part and / or panel.

[0036] In some implementations, a photoluminescent structure 42 may be included in the vehicle part as one or more discrete multilayer particles, as shown in FIG. 2C. The photoluminescent structure 42 may also be provided as one or more discrete multilayer particles dispersed in a polymer composition, which is subsequently applied to the vehicle part or panel as an adjacent structure. Additional information regarding the construction of photoluminescent structures to be used in at least one photoluminescent fragment of a vehicle is disclosed in US Pat. EMISSION ", registered July 31, 2012, the full disclosure of which is incorporated herein by reference.

[0037] Referring to FIG. 3, the lighting system 12 is generally shown according to a configuration with a backlight to convert the first radiation 16 from at least one light source 14 into a second radiation 20. The first radiation 16 contains a first wavelength λ ₁ , and the second radiation 20 contains the second wavelength λ ₂ waves. The lighting system 12 may include a photoluminescent structure 42, presented as a coating and deposited on the substrate 64 of the vehicle part 66. The photoluminescent structure 42 may include an energy conversion layer 44, and in some implementations may include a resistance layer 46 and / or a protective layer 48. In response to the activation of at least one light source 14, the first radiation 16 is converted from a first length λ ₁ waves into the second radiation 20 having at least a second wavelength λ ₂ . The second radiation 20 may comprise a plurality of wavelengths configured to emit substantially white light from the vehicle part 66.

[0038] In various implementations, the lighting system 12 comprises at least one energy conversion layer 44 configured to convert the first radiation 16 with a first wavelength λ ₁ into second radiation 20 having at least a second wavelength λ ₂ . At least one energy conversion layer 44 may be configured to produce many visible colors using at least one of a red light emitting photoluminescent material, emitting green light of a photoluminescent material, and emitting blue light of a photoluminescent material scattered in the polymer matrix 50. Emitting red , green and blue light photoluminescent materials can be combined to form substantially white light for the second radiation 20. Advanced tively, emitting red, green and blue light photoluminescent materials can be used in a variety of proportions and combinations in order to control the output of the second emission color 20.

[0039] Each of the photoluminescent materials may vary in output intensity, output wavelength, and peak absorption wavelengths based on a particular photochemical structure and combinations of photochemical structures used in the energy conversion layer 44. The intensity of the second radiation 20 can be changed by adjusting the wavelength of the first radiation. In addition to or alternatively emitting red, green, and blue light to the photoluminescent materials, other photoluminescent materials can be used individually and in various combinations to form the second radiation 20 in a wide variety of colors. Thus, the lighting system 12 can be configured for a variety of applications to provide the desired lighting color and effect for the vehicle 10.

[0040] At least one light source 14 may refer to a plurality of light sources including a first light source 22 and a second light source 26. At least one light source 14 may also be called an excitation source and functions to emit at least the first radiation 16. At least one light source 14 may contain any form of light source, for example, halogen lighting, fluorescent lighting, light emitting diodes (LED), organic LEDs (OLED), polymer LEDs (PLED), solid state lighting or any other form of lighting, configured to output the first radiation 16.

[0041] Turning now to FIG. 4, the lighting system 12 is shown in a configuration comprising a plurality of photoluminescent fragments 80 including a first photoluminescent fragment 24 and a second photoluminescent fragment 30. The first photoluminescent fragment 24 is configured to emit a second radiation 20 in response to receiving the first radiation 16 from the first source 22 Sveta. The second photoluminescent fragment 30 is configured to emit the fourth radiation 32 in response to receiving the third radiation 28 from the second light source 26. Each of the plurality of photoluminescent fragments 80 can be independently excited. For example, the second radiation 20 may be output, while the fourth radiation 32 may be inactive, and the fourth radiation 32 may be output, while the second radiation 20 may be inactive. This selective activation of each of the photoluminescent fragments 80 can be realized using photoluminescent materials having non-overlapping absorption ranges.

[0042] In some implementations, the first radiation 16 from the first light source 22 can be configured such that the first wavelength λ ₁ corresponds to the first absorption range of the first photoluminescent fragment 24. The third radiation 28 from the second light source 26 can be configured so that a third length λ ₃ waves corresponds to the second absorption range of the second photoluminescent fragment 30. The first absorption range may correspond to the absorption range of light radiation, which differs significantly from the second absorption range. In this configuration, the first light source 22 can selectively activate the first photoluminescent fragment 24 with the first radiation 16 in the first absorption range, and the second light source 26 can selectively activate the second photoluminescent fragment 30 with the third radiation 28 in the second absorption range.

[0043] Turning now to FIG. 5, an exemplary graphical representation 84 of the conversion of the first radiation 16 to the second radiation 20 and the third radiation 28 to the fourth radiation 32 is shown. The independent axis 86 of the graph 84 shows the absorption range in nanometers that corresponds to the wavelengths of the light absorbed by the photoluminescent materials and the corresponding photoluminescent fragments 24 and 30. The dependent axis 88 shows the percentage of fluorescence radiation in the photoluminescent ranges as a function of radiation absorption. Each of the emissions 20 and 32 from the photoluminescent fragments 24 and 30 is configured to output light with one or more wavelengths corresponding to specific realized photoluminescent materials.

[0044] In this example, a graphical representation 84 shows a first absorption range 90 and a second absorption range 92 and each of the corresponding light emissions (for example, second radiation 20 and fourth radiation 32). The first absorption range 90 corresponds to longer light wavelengths than the second absorption range 92. Thus, the first photoluminescent fragment 24 can be illuminated independently of the second photoluminescent fragment 30. The absorption ranges and resulting radiation can be configured by the specific photoluminescent materials used in each of the photoluminescent fragments 24 and 30. Various combinations of photoluminescent materials can provide a wide range colors and wavelength combinations to create a motion effect.

[0045] The term "absorption range", as used herein, defines a range of wavelengths that excite a photoluminescent fragment or structure and cause the photoluminescent fragment to become excited. In response to the excitation, the photoluminescent fragment emits radiation having at least one wavelength of light that is at least partially outside the absorption range. In various implementations, the absorption range of photoluminescent materials, as discussed herein, may vary. Additionally, light emission in the form of an emitted glow can be selected based on the material properties of the photoluminescent structures discussed herein.

[0046] Turning now to FIG. 4 and 5, an example of a specific combination of photoluminescent materials and light sources is shown. The first absorption range 90 may correspond to a wavelength range in the blue and / or near UV light range having wavelengths of approximately 390-450 nm. The second absorption range 92 may correspond to a substantially non-overlapping wavelength range of UV and / or blue light range having wavelengths of approximately 250-410 nm. The first radiation 16 may have a wavelength of approximately 470 nm, and be configured to cause the first photoluminescent fragment 24 to output the second radiation 20, approximately equal to 525 nm. The third radiation 28 may have a wavelength of approximately 370 nm, and be configured to cause the second photoluminescent fragment 30 to output the fourth radiation 32 with a wavelength of approximately 645 nm. Thus, the second radiation 20 and the fourth radiation 32 can be selectively excited by each of the light sources 22, 26 in order to independently output almost green light and almost orange-red light, respectively.

[0047] In general, the photoluminescent materials of the first photoluminescent fragment 24 and the second photoluminescent fragment 30 can be combined in various proportions, types, layers, etc., to form a plurality of colors for each of the luminescent radiation. Although specific materials and structures of photoluminescent materials are discussed herein, various materials can be used without departing from the spirit of the invention. In some implementations, the first photoluminescent fragment 24 is configured to have a first absorption range 90, which is significantly larger than the second absorption range 92. Additionally, the second wavelength λ _{2 of the} second radiation 20 can be configured to output a significantly shorter wavelength or wavelength range than the fourth wavelength λ _{4 of the} fourth radiation 32.

[0048] In some implementations, the first photoluminescent fragment 24 may comprise an organic fluorescent dye configured to convert the first radiation 16 to a second radiation 20. For example, the first photoluminescent material may comprise a photoluminescent structure of rayenes, xanthenes, porphyrins, phthalocyanines or other materials suitable for a specific Stokes shift defined by the range of absorption and emission of radiation. The first photoluminescent fragment 24 and the corresponding material may be configured to have a shorter Stokes shift than the second photoluminescent fragment. Thus, each of the photoluminescent fragments 24 and 30 can be independently illuminated by the light sources 22 and 26 to output different colors of light.

[0049] The second photoluminescent fragment 30 may comprise a photoluminescent structure 42 configured to generate a longer Stokes shift than the first photoluminescent fragment 24. The second photoluminescent fragment may contain organic or inorganic material configured to have a second absorption range 92 and a desired output length waves or color. In an exemplary embodiment, the photoluminescent structure 42 of the second photoluminescent fragment 30 may be from at least one inorganic luminescent material selected from the group of phosphors. The inorganic luminescent material may more specifically be from the group of cerium-doped garnets, such as YAG: Ce. This configuration may ensure that the second Stokes shift of the second photoluminescent fragment 30 is greater than the first Stokes shift of the first photoluminescent fragment 24.

[0050] The first radiation 16 and the third radiation 28 from light sources are shown to have wavelengths in the blue spectral color range and shorter wavelengths (UV wavelengths). Such wavelengths can be used as excitation sources for photoluminescent fragments and provide almost imperceptible light sources due to these wavelengths having limited perceptual acuity in the visible spectrum of the human eye. Using shorter wavelengths for the excitation sources (for example, the first radiation 16 and the third radiation 28), the lighting system 12 can create a visual effect of light coming from the photoluminescent fragments 24 and 30. Additionally, in this configuration, light is emitted from the photoluminescent structure 42 (for example, the first photoluminescent fragment 24, the second photoluminescent fragment 30) from places of the vehicle 10, which may be unavailable or expensive to add traditional light sources, rebuyuschie electrical connections.

[0051] In order to achieve the various colors and combinations of the photoluminescent materials described herein, the lighting system 12 may use any form of photoluminescent materials, for example, photoluminescent materials, organic and inorganic dyes. For additional information regarding the manufacture and use of photoluminescent materials in order to achieve different emissions, refer to US Patent No. 8,207,511 Boratza et al., Entitled "PHOTOLUMINESCENT FIBERS, COMPOSITIONS AND FABRICS MADE THEREFROM", filed June 26, 2012; U.S. Patent No. 8,247,761 to Agraival and the like, entitled "PHOTOLUMINESCENT MARKING WITH FUNCTIONAL OVERLAYERS", registered August 21, 2012; US Pat. No. 8,519,359 B2 to Kingsley et al., entitled "PHOTOLYTICALLY AND ENVIRONMENTALLY STABLE MULTIPLAYER STRUCTURE FOR HIGH EFFICIENCY ELECTROMAGNETIC ENERGY CONVERSION ADN SUSTAINED SECONDARY EMISSION" of August 27, 2013; US Patent No. 8,644,624 B2 Kingsley et al., entitled "ILLUMINATION DELIVERY SYSTEM FOR GENERATING SUSTAINED SECONDARY EMISSION", registered March 4, 2014; US Patent Publication No. 2012/0183677 of Agriewal et al., entitled "PHOTOLUMINESCENT COMPOSITIONS, METHODS OF MANUFACTURE AND NOVEL USES", filed July 19, 2012; US Patent Publication No. 2014/0065442 A1 Kingsley et al., entitled "PHOTOLUMINESCENT OBJECTS", registered March 6, 2014; and U.S. Patent Publication No. 2014/0103258 A1 of Agraival, etc., entitled "CHROMIC LUMINESCENT COMPOSITIONS AND TEXTILES", filed April 17, 2014, all of which are incorporated herein by reference in their entirety.

[0052] Referring to FIG. 6A-6C show detailed views of a first photoluminescent fragment 24 and a second photoluminescent fragment 30 showing a motion effect and / or combined directional lighting in accordance with the invention. As discussed herein, the lighting system 12 functions to selectively illuminate the first photoluminescent fragment 24 by emitting the first radiation 16 from the first light source 22. The lighting system 12 additionally functions to selectively illuminate a second photoluminescent fragment 30 by emitting a third radiation 28 from a second light source 26. Each of the light sources 22 and 26 can be selectively activated by one or more lighting controllers configured to control the first and second light sources 22 and 26.

[0053] The light sources 22 and 26 can be activated in combination or periodically to create a visual effect, for example, flicker, wobble, animated movement, etc. When activated in combination, as shown in FIG. 6C, the combination of the second radiation 20 and the fourth radiation 32 provides the simultaneous output of the first color 100 of light corresponding to the second wavelength λ _{2 of the} wave and the second color 102 of light corresponding to the fourth wavelength λ _{4 of the} wave. As shown in FIG. 5, a second wavelength λ ₂ and a fourth wavelength λ ₄ each may correspond to one or more wavelengths combined to form an averaged or perceived color of light. Each of the first color 100 and the second color 102 may correspond to different perceived colors or shades of colors that can be selectively output to form a motion effect.

[0054] Turning now to FIG. 7A and 7B, detailed views of a first photoluminescent fragment 112 and a second photoluminescent fragment 114 are shown, showing a fading or moving lighting effect that can be configured to generate a plurality of light colors. In this example, each of the photoluminescent fragments 112 and 114 may be similar to the first photoluminescent fragment 24 and the second photoluminescent fragment 30 in that the first photoluminescent fragment is primarily illuminated in response to the first radiation 16 from the first light source 22, and the second photoluminescent fragment first of all, it is illuminated in response to the third radiation 28 from the second light source 26. In this configuration, the first light source 22 and the second light source 26 can be configured to produce a moving, fading and / or pulsating lighting effect by controlling the intensity and directional focus of the first light source 22 and the second light source 26.

[0055] Each of the photoluminescent fragments 112 and 114, as shown, forms a selectively illuminated fragment 116, which may correspond to a coating deposited on the surface 118 of the vehicle 10, and / or at least one photoluminescent material scattered in the paint or coating applied to surface 118. For clarity, selectively illuminated fragment 116 is shown as a simple trapezoidal shape, however, selectively illuminated fragment 116 may correspond to any shape, pattern, accent, and / or combination thereof. Additionally, the first photoluminescent fragment 112 may correspond to a first shape or pattern, and the second photoluminescent fragment 114 may correspond to a second shape or pattern, each having different sizes and / or proportions. The first photoluminescent fragment 112 may also partially or completely overlap the second photoluminescent fragment 114 in the selectively illuminated fragment 116.

[0056] As shown in FIG. 7A and 7B, the first photoluminescent fragment 112 is shown as a first pattern of lines extending diagonally downward from the upper left border of a selectively illuminated fragment 116 to the lower right border of a selectively illuminated fragment 116. The second photoluminescent fragment 114 is shown as a second pattern of lines extending upward diagonally from the lower left border of the selectively lit fragment 116 to the upper right border of the selectively illuminated fragment 116. For clarity, each of the photoluminescent fragments 112 and 114 d is monstered as having the same length to the borders of the selectively illuminated fragment 116. However, each of the photoluminescent fragments can be applied to any fragment of the surface 118 or any other surface of the vehicle 10, where the light sources 22 and 26 can be directed.

[0057] Referring to FIG. 7A, a second light source 26 is shown as a second plurality of lighting devices 120. The lighting system 12 operates to create a second gradient of light or a pattern 122a of light emitted as the third radiation 28, as demonstrated by the length of each of the arrows indicating the third radiation 28. Corresponding the light pattern 122a, the illuminated region 124a of the second photoluminescent fragment 114 may be excited to emit a fourth radiation 126. The first light source 22 contains a first plurality of lighting devices at 130 and also functions to create a first gradient of light or a pattern 132a of light emitted as the first radiation 16, as shown by the length of each of the arrows indicating the first radiation 16. The illuminated region 134a of the first photoluminescent fragment 112 corresponding to the light pattern 132a is excited to emit a second radiation 136. In this configuration, each of the light sources 22 and 26, and their respective lighting devices 130 and 120, function to selectively illuminate various patterns and fragments of light. each of the photoluminescent fragments 112 and 114.

[0058] Referring to FIG. 7B, as another example, the lighting system 12 functions to form a first gradient of light or a light pattern 132b emitted as the first radiation 16, as shown by the length of each of the arrows indicating the first radiation 16. The illuminated area 134b of the first corresponding to the light pattern 132b a photoluminescent fragment 112 is excited to emit a second radiation 136. The second light source 26 contains a second plurality of lighting devices 120 and also functions to form a second gradient a eta or pattern 122b of light emitted as the third radiation 28. The illuminated region 124b of the second photoluminescent fragment 114 corresponding to the light pattern 122b is excited to emit the fourth radiation 126.

[0059] Various illumination emissions and corresponding patterns emitted from the first plurality of lighting devices 130 and the second plurality of lighting devices 120 may be configured to illuminate various spaces, fragments and patterns of photoluminescent emissions from surface 118. Photoluminescent emissions are selectively generated by each of the lighting devices 130 and 120 by exciting the photoluminescent materials of the first photoluminescent fragment 112 and the second photoluminescent fragment 114. Ra The distinct patterns of light emitted from the photoluminescent fragments 130 and 120 can be controlled by the light intensity and the selective illumination of each lighting device from the lighting devices 130 and 120. In this configuration, the lighting system 12 operates to generate various light patterns and lighting effects on the surface 118 of the transport means 10. In some implementations, the lighting system 12 functions to form fading, moving, pulsating and various other lighting patterns, a choice Normally the second activating radiation 136 and the fourth radiation 126 in response to the activation of the first plurality of illumination devices 130, and a second plurality of lighting devices 120.

[0060] As discussed herein, the first photoluminescent fragment 112 and the second photoluminescent fragment 114 may correspond to a first color and a second color, respectively. Each of the photoluminescent fragments 112 and 114 may also be configured to have a first absorption range 90 and a second absorption range 92, as discussed with reference to FIG. 5. In general, the first absorption range and the second absorption range may correspond to substantially different ranges or partially overlapping wavelength ranges of light emitted from the first light source 22 and the second light source 26. In an example in which the first and second absorption ranges correspond to substantially different wavelengths of light, the first photoluminescent fragment 112 and the second photoluminescent fragment 124 can be independently excited by their respective light sources 22 and 26. In an example in which the first absorption range and the second absorption range partially overlap, the first photoluminescent fragment 112 and the second photoluminescent fragment 124 can be partially excited by each of the light sources 22 and 26 to change the intensity and create the effect of mixing the first photoluminescent fragment 122 and the second photoluminescent fragment.

[0061] For example, the first light source 22 may illuminate the first photoluminescent fragment 112 with an efficiency of approximately 90 percent, as well as illuminate the second photoluminescent fragment 114 with an efficiency of approximately 40 percent. The effectiveness of each of the light sources 22 and 26 to illuminate the photoluminescent fragments 112 and 114 can be controlled by selecting light sources that emit the desired wavelengths of light. The desired wavelengths of light may correspond to different fragments of the absorption range of a particular photoluminescent material or a combination of photoluminescent materials. In this configuration, the first light source 22 may function to mix the first color emitted from the first photoluminescent fragment 112 with the second color emitted from the second photoluminescent fragment 114. Similarly, the second light source 26 may function to mix the second color emitted from the second a photoluminescent fragment 114, with a first color emitted from the first photoluminescent fragment 112. By varying intensities from each lighting device from a plurality of lighting devices 1 30 and 120, the lighting system functions to create a variety of light colors, light patterns, motion effects, and combinations thereof.

[0062] In some implementations, the first photoluminescent fragment 112 may further be configured to emit a plurality of light colors from the first plurality of color fragments 140. For example, the first photoluminescent fragment 112 may comprise a first color fragment 142, a second color fragment 144, and a third color fragment 146. Each of the color fragments 142, 144, 146 may be configured to be excited with different levels of efficiency in response to the first radiation 16 from the first light source 22. Additionally, the second photoluminescent fragment 114 may be configured to emit a plurality of light colors from the second plurality of color fragments 150. The second photoluminescent fragment 114 may comprise a fourth color fragment 152, a fifth color fragment 154, and a sixth color fragment 156. Each of the color fragments 152, 154 156 may be configured to be excited at various levels of efficiency in response to the second radiation 28 from the second light source 26.

[0063] Although the color fragments 142, 144, 146, 152, 154 and 156 are shown as overlapping fragments of the first photoluminescent fragment 112 and the second photoluminescent fragment 114, each of the color fragments can be applied to different and / or partially overlapping fragments of surface 118. Thus thus, the lighting system 12 provides illumination of various patterns, colors, patterns, lighting effects, and motion effects. The lighting system 12 functions to control the intensity of each color fragment 142, 144, 146, 152, 154, and 156 at different levels and intensities, controlling each lighting device from a plurality of lighting devices 130, 120. As demonstrated by the various examples and configurations described in Throughout this document, the lighting system provides a flexible lighting system that functions to provide a variety of lighting effects. The lighting system 12 also has the added benefit of functioning to create various lighting effects while maintaining a low implementation cost.

[0064] The invention provides a lighting system 12 configured to output light from a plurality of photoluminescent fragments to create a motion effect. Various implementations provide a variety of photoluminescent materials that can be selectively activated to create a motion effect in response to the activation of multiple light sources. System 12 provides various benefits, including the creation of visual effects to enhance the appearance of the vehicle. In some implementations, system 12 may be used to display messages or characters on at least one vehicle panel. Additionally, at least one of the photoluminescent fragments can be used to selectively identify hidden vehicle identification information, for example, a secret law enforcement vehicle.

[0065] It should be understood that variations and modifications may be made according to the above structure without departing from the concepts of the present invention, and it should further be understood that such concepts are intended to be embraced by the following claims, unless the claims expressly state otherwise by their language.

Claims (22)

1. A lighting device for a vehicle, comprising: at least one vehicle panel containing a first photoluminescent fragment containing a first luminescent absorption range configured to generate a first output color, and a second photoluminescent fragment containing a second luminescent absorption range configured to generate a second output color, wherein the first a photoluminescent fragment overlaps the second photoluminescent fragment, forming an overlapping fragment; and the first light source is located close to and separately from the vehicle panel, configured to emit a first radiation with a first wavelength, the first wavelength being in the first absorption range and outside the second absorption range. 2. The lighting device according to claim 1, wherein the first luminescent absorption range corresponds to a range of light wavelengths other than the second absorption range. 3. The lighting device according to claim 1, further comprising: a second light source configured to emit a second radiation with a second wavelength different from the first wavelength and in the second absorption range. 4. The lighting device according to claim 3, which is also configured to emit the first radiation together with the second radiation and in response to receiving the first radiation and the second radiation, the overlapping fragment emits a third output color. 5. The lighting device according to claim 4, which is also configured to control the first intensity of the first radiation and the second intensity of the second radiation, wherein the hue of the third output color is controlled based on the first intensity and second intensity. 6. The lighting device according to claim 1, wherein the first photoluminescent fragment forms a first pattern located on the outer surface of the vehicle panel. 7. The lighting device according to claim 6, in which the second photoluminescent fragment forms a second pattern on the outer surface of the vehicle panel, different from the first pattern. 8. The lighting device according to claim 7, wherein the controller is configured to illuminate the first pattern substantially independently of the second pattern. 9. A lighting system configured to illuminate a vehicle panel, comprising: a plurality of light sources configured to emit a first radiation and a second radiation; and a coating located on the vehicle panel separately from and close to the light source, the coating comprising a plurality of overlapping fragments extending longitudinally along the surface of the panel, the overlapping fragments emitting: a first output color in response to the first radiation; a second output color in response to the second radiation; and a third output color in response to a combination of the first radiation and the second radiation. 10. The lighting system of claim 9, wherein the vehicle panel comprises a sketch surface comprising a sketch angle extending outward from the light source so that the first radiation is received by a significant portion of the photoluminescent fragment. 11. The lighting system according to claim 9, in which the coating contains a light-guiding film located substantially equally along the length of the coating. 12. The lighting system of claim 9, wherein the coating is configured to transmit and scatter the first radiation longitudinally relative to the panel in the direction of the first radiation. 13. The lighting system of claim 9, wherein the third output color comprises a transitional hue with a first output color and a second output color. 14. A lighting system for a vehicle, comprising: a controller in conjunction with a light source configured to emit a first radiation and a second radiation; and a first photoluminescent fragment overlapping the second photoluminescent fragment on the surface of the vehicle panel separately from and close to the light source, wherein the controller is configured to independently illuminate the first photoluminescent fragment and the second photoluminescent fragment by activating the exciting radiation, respectively. 15. The lighting system according to claim 14, wherein the second photoluminescent fragment is configured to have a significantly inert state in response to the first radiation, wherein the inert state corresponds to the second photoluminescent fragment releasing a proportionally small portion of the light relative to the first photoluminescent fragment. 16. The lighting system according to claim 14, in which the second photoluminescent fragment contains many colored parts, configured to emit many colors of light in response to receiving the second radiation. 17. The lighting system of claim 14, wherein the controller is also configured to illuminate both the first photoluminescent fragment and the second photoluminescent fragment in response to receiving both the first excitation radiation and the second excitation radiation.

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