RU2686980C2 - Photoluminescent changing color ceiling lamp for card illumination - Google Patents

Abstract

FIELD: vehicles; lighting devices.SUBSTANCE: group of inventions relates to lighting devices for a vehicle. Lighting device comprises a single-color light source configured to emit first radiation of the first color in the blue spectral range and associated with the controller. First color is configured to excite the photoluminescent portion to emit white light. Controller is configured to adjust output color of second radiation output from photoluminescent part, by adjusting the forward driving current and the relative duration of the single-color light source such that the intensity of the first radiation exceeds the photoluminescent part conversion capacity.EFFECT: higher quality of common and working illumination.19 cl, 8 dwg

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a partial continuation of the application for the grant of US patent No. 14 / 301,635, filed on June 11, 2014 and entitled “PHOTOLUMINESCENT LAMP FOR READING A VEHICLE” (“PHOTOLUMINESCENT VEHICLE READING LAMP”), which is a partial continuation of the patent application of a patent No. 14 / 156,869, filed January 16, 2014, entitled “VEHICLE DOME LIGHTING SYSTEM WITH PHOTOLUMINESCENT STRUCTURE”, CEILING LIGHTING SYSTEM OF A VEHICLE LIGHTING SYSTEM WITH A PHOTOLUMINESCENT STRUCTURE. The above-mentioned related applications are hereby incorporated by reference in their entirety.

TECHNICAL FIELD OF THE INVENTION

The present invention relates generally to lighting devices, and more specifically, to a lighting device configured to adjust the color of the output light.

BACKGROUND OF INVENTION

Illumination originating from photoluminescent materials offers a unique and attractive viewing experience. Therefore, it is desirable to include such photoluminescent materials in parts of vehicles to provide general and working light.

SUMMARY OF INVENTION

According to one aspect of the present invention, a vehicle lighting device is disclosed. The lighting device contains at least one light source in communication with the controller. The light source is configured to emit the first radiation to excite the photoluminescent part. The controller is operable to adjust the output color of the emitted light from the light source by adjusting the intensity of the light output from at least one light source.

According to another aspect of the present invention, an illumination device for a vehicle is disclosed. The lighting device comprises a light source adapted to emit the first radiation. The photoluminescent part is located closer to the light source and is configured to convert at least part of the first radiation into the second radiation. The lighting device further comprises a controller, the controller is configured to adjust the color of the second radiation by selectively adjusting the intensity of the first radiation.

According to still another aspect of the present invention, a lighting device for a vehicle is disclosed. The lighting device comprises a light source in communication with the controller, and configured to emit the first radiation. The photoluminescent part is located closer to the light source and is configured to convert at least part of the first radiation into the second radiation. The controller is configured to control the first radiation with the first intensity to output the second radiation in the ceiling light configuration corresponding to the first color and control the first radiation with the second intensity to output the second radiation in the read light configuration corresponding to the second color.

These and other aspects, objectives and features of the present invention will be understood and appreciated by experts in the field of technology to study the following description of the invention, the claims and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the drawings:

FIG. 1 is a schematic diagram illustrating a front passenger compartment of a vehicle having a cantilever above a windshield using at least one lighting device;

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

FIG. 2B illustrates a photoluminescent structure presented as a discrete particle;

FIG. 2C illustrates a plurality of photoluminescent structures represented as discrete particles and included in a separate structure;

FIG. 3 is a schematic view of a backlit configuration of an illumination device configured to convert a first wavelength of light into at least a second wavelength;

FIG. 4 - a graphic image of radiation from a light source;

FIG. 5 is a graphical depiction of the absorbance and fluorescence of the photoluminescent material;

FIG. 6 is a schematic diagram illustrating an implementation of a lighting device.

FIG. 7 is a schematic diagram illustrating an implementation of a lighting device; and

FIG. 8 is a schematic diagram illustrating implementations of the lighting device in accordance with the disclosure.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

As required, detailed embodiments of the present disclosure are disclosed herein. However, it should be understood that the disclosed embodiments are merely examples of disclosure, which may be embodied in various and alternative forms. Figures are not necessarily intended for detailed design, and some diagrams may be exaggerated or understated to show the general purpose. Therefore, the specific structural and functional details disclosed in the materials of this application should not be interpreted as limiting, but only as a basis for studying by a person skilled in the art for various uses of the present disclosure.

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 used by itself, or any combination of two or more of the listed elements can be used. For example, if a composition is described as containing components A, B, and / or C, the composition may contain exclusively A; exclusively B; exclusively C; A and B in combination; A and C in combination; B and C in combination; or A, B and C in combination.

The subsequent disclosure describes a vehicle lighting device configured to highlight at least a portion of the passenger compartment. The lighting system may be configured to operate in at least the first state and the second state. The first state may correspond to a ceiling light function configured to emit light from the illumination device, which is essentially white, having a warm shade. The second state may correspond to the function of light for reading, made with the ability to emit light from the lighting device, which is essentially white, having a cool blue tint. The emitted light corresponding to the second state may have an increased intensity relative to the emitted light in the first state. Thus, the lighting device can be configured to highlight the passenger compartment of the vehicle in a shade of white light that is best adapted to the specific activity of the passenger or driver.

Referring to FIG. 1, a generally illustrated passenger compartment 10 of a vehicle 12 has at least one lighting device 14 mounted in a console 16 above a windshield. In the illustrated implementation, the console 16 above the windshield is mounted on the inside of the headliner of the passenger compartment 10 and is located in a central location in the passenger compartment 10. In the example shown, two lighting devices 14 are mounted on the console 16 above the windshield, one is positioned to give greater access to the driver of the vehicle 12, and the other is located to give greater access to the passenger or the driver of the vehicle 12. Despite the fact that the two lighting devices units 14 were generally shown in FIG. 1, it must be taken into account that one or more lighting devices 14 may be enclosed in other locations of the console 16 above the windshield or other locations aboard the vehicle 12.

One or more switches 18 may be configured to provide the passenger or driver with the ability to manually activate the lighting devices 14. As shown, for example, the switch 18 is located closer to each of the lighting devices 14 to provide each lighting device 14 with the ability to be controlled independently. Additionally or alternatively, one or more switches 18 may be located anywhere on board the vehicle 12, for example, on the shield 20 of the vehicle. Should be taken into account that the switch 18 may be located in other locations within the vehicle 12, such as, but not by way of limitation, the driver's side door, the passenger side door and / or the center console zone. In some implementations, the lighting controller of the vehicle 12 may also be configured to selectively activate the lighting devices 14. In this configuration, the lighting controller and / or the passenger or driver of the vehicle 12 may be operable to activate each of the lighting devices 14 in the first state 22, which may correspond to the function of the ceiling light, and the second state 24, which may correspond to the function of the reading light.

In some implementations, the lighting device 14 may contain a photoluminescent portion 26 located along the path of the first radiation 28. The first radiation 28 may be output from a light source located in the lighting device 14. In some implementations, the photoluminescent portion 26 may be located in and / or an optical device configured to emit the first radiation 28. The lighting device 14 may be configured to pass the first radiation 28 through the photoluminescent part 26, from the condition that the first radiation 28 is converted to the second radiation 30. The first radiation 28 may correspond to the first wavelength of light, and the second radiation 30 may correspond to at least the second wavelength of light. The second wavelength of light may contain at least one wavelength greater than the first wavelength of light. As soon as the first radiation 28 is converted, the second radiation 30 can be output as emitted light 32 from the lighting device 14 to illuminate at least part of the passenger compartment 10.

In some implementations, the lighting device 14 may be operable to selectively output the emitted light 32 in the first state 22 or the second state 24, in response to a control signal received from the lighting controller and / or from one or more switches 18. In the first state 22 The light source of the lighting device 14 may be configured to emit the first radiation 28 with a first intensity. In the second state 24, the light source of the illumination device 14 may be configured to emit the first radiation 28 with a second intensity greater than the first intensity. As further described throughout this disclosure, the lighting device 14 may be operable to control the intensity of the first radiation 28 outputted from the light source to control the color of the emitted light 32.

Referring to FIG. 2A-2C generally shows a photoluminescent structure 42 represented as a coating (e.g., film), allowing a discrete particle to be deposited on an optical device, capable of being inserted into an optical device, and a plurality of discrete particles included in a separate structure that can be applied to an optical device, respectively. The photoluminescent structure 42 may correspond to the photoluminescent part 26, as discussed herein. At the most basic level, the photoluminescent structure 42 includes an energy conversion layer 44, which can be provided as a single layer or a multilayer structure, as shown by the broken lines in FIG. 2A and 2B.

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 compiled to convert the input electromagnetic radiation into output electromagnetic radiation, usually having a longer wavelength and expressing a color that is not characteristic of the input electromagnetic radiation. The difference in wavelength between input and output electromagnetic radiation is indicated by reference as the Stokes shift and serves as the principal driving mechanism for the energy conversion process, corresponding to a change in the wavelength of light, often referred to as a down-conversion. In the various implementations discussed in the materials of this application, each of the wavelengths of light (for example, the first wavelength, etc.) corresponds to electromagnetic radiation that can be used in the conversion process.

The photoluminescent portion 26 may comprise at least one photoluminescent structure 42 comprising an energy conversion layer (for example, a conversion layer 44). The energy conversion layer 44 can be prepared by spreading the photoluminescent material in the polymer matrix 50 to form a homogeneous mixture using a variety of methods. Such methods may include preparing an energy conversion layer 44 from a composition in a liquid carrier medium and applying an energy conversion layer 44 to a desired flat and / or non-planar substrate, for example, the surface of an optical device. The energy conversion layer 44 may be applied to the optical device by dyeing, screen printing, spraying, slit coating, dip coating, roll coating and plank coating. Additionally, the energy conversion layer 44 may be prepared by methods that do not use the carrier liquid.

For example, a solid solution (a homogeneous mixture in a dry state) of one or more photoluminescent materials may be incorporated into the polymer matrix 50 to provide an energy conversion layer 44. The polymer matrix 50 can be formed by extrusion, injection molding, pressure molding, extrusion, thermoforming, etc. In cases where one or more energy conversion layers 44 are presented as particles, single or multilayer energy conversion layers 44 can be embedded in an optical device or part of a lighting device 14 configured to be at least partially translucent. When the energy conversion layer 44 includes a multi-layer composition, each layer can be coated sequentially. Additionally, the layers can be prepared separately, and later layered or embossed with each other to form a solid layer. Layers can also be jointly extruded to prepare a single multi-layer energy conversion structure.

Returning to FIG. 2A and 2B, the photoluminescent structure 42 may optionally include at least one stability layer 46 to protect the photoluminescent material contained within the energy conversion layer 44 from photolytic and thermal degradation. Stability layer 46 can be configured as a layer optically bonded and adhered to energy conversion layer 44. Stability layer 46 can also be combined with energy conversion layer 44. The photoluminescent structure 42 may also optionally include a protective layer 48 optically bonded and spliced with a layer 46 of stability or some kind of layer or coating to protect the photoluminescent structure 42 from physical and chemical damage caused by environmental factors.

Stability layer 46 and / or protective layer 48 can be combined with energy conversion layer 44 to form a single photoluminescent structure 42 by sequential coating or printing each layer, or by successive layering or embossing. Alternatively, several layers may be combined by successive coating, layering or embossing to form a substructure. The substructure may then be layered or embossed to form a single photoluminescent structure 42. Once formed, the photoluminescent structure 42 may be applied to a portion of the lighting device 14, configured to convert at least a portion of the first radiation to the second radiation 30. In some implementations, photoluminescent structure 42 may be deposited on / located in an optical device for forming a photoluminescent portion 26.

In some implementations, the photoluminescent structure 42 may be included in the optical device 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 concentrated in a polymer matrix 50, which is subsequently applied to an optical device or part of a lighting device 14 as an adjacent structure. Additional information regarding the structure of the photoluminescence WITH LONG-TERM SUSPENSION OF SECONDARY RADIATION "(" PHOTOLYTICALLY AND ENVIRONMENTALLY STABLE MULTILAYER STRUCTURE FOR HIGH EFFICIENCY ELECTROMAGNETIC ENERGY CONVERSION AND SUSTAINED SECONDARY EMISSION "), c. th feed July 31, 2012, the entire disclosure of which is incorporated herein by reference.

Referring to FIG. 3, the lighting device 14 is generally shown according to the backlit configuration 60. In this configuration, the first radiation 28 emitted from the light source 62 is converted into the second radiation 30 by the energy conversion layer 44. The first radiation 28 contains the first wavelength, and the second radiation 30 contains the second wavelength. The lighting device 14 contains a photoluminescent structure 42 located on or in the photoluminescent part 26. The photoluminescent structure 42 may be provided as a coating and applied to the optical device 64, for example, at least a partially translucent part of the lighting device 14. The photoluminescent material may also be dispersed as the polymer matrix 50 corresponding to the energy conversion layer 44.

In some implementations, the energy conversion layer 44 may additionally include a stability layer 46 and / or a protective layer 48. In response to the activation of the first light source 62, the first radiation 28 may be received by the energy conversion layer 44 and converted from the first radiation 28 having the first wavelength, to the second radiation 30, having at least a second wavelength. The second radiation 30 may contain multiple wavelengths, made with the ability to emit any color of light from the photoluminescent part 26.

In various implementations, the lighting device 14 contains at least one photoluminescent material enclosed in a polymer matrix 50 and / or an energy conversion layer 44 and adapted to convert the first radiation 28 with the first wavelength into the second radiation 30 having at least a second length the waves. In order to generate multiple wavelengths, the energy conversion layer 44 may contain one or more photoluminescent materials configured to emit a second radiation 30 as wavelengths of light in the red, green and / or blue color spectra. Such photoluminescent materials can additionally be combined to form a wide variety of colors of light for the second radiation 30. For example, photoluminescent materials emitting red, green and blue radiation can be used in a variety of proportions and combinations to control the output color of the second radiation 30.

Each of the photoluminescent materials can differ in output intensity, output wavelength and peak absorption wavelengths based on the specific photochemical structure and combinations of photochemical structures used in the energy conversion layer 44. As an example, the second radiation 30 can be changed by adjusting the length of the 28 wave of the first radiation to introduce photoluminescent materials at different intensities to change the color of the second radiation 30. In addition or as an alternative to emitting red, green and blue light photoluminescent materials other photoluminescent materials can be used alone and in various combinations to form the second radiation 30 in a wide variety of colors. Thus, the lighting device 14 can be configured for a variety of applications to give the desired color and lighting effect to the vehicle.

To achieve different colors and combinations of photoluminescent materials described in the materials of the present application, the lighting device 14 can use any form of photoluminescent materials, for example, photoluminescent materials, organic and inorganic dyes, etc. For further information regarding the manufacture and use of photoluminescent materials for achievements of various radiations, see US Patent No. 8,207,511 for Bortz and others, entitled “PHOTOLUMINESCENT FIBERS, MOPPOSITES AND FABRICS MADE OF THEM ”(“ PHOTOLUMINESCENT FIBERS, COMPOSITIONS AND FABRICS MADE THEREFROM ”), with a filing date of 26 June 2012; U.S. Patent No. 8,247,761 to Agravala and others, entitled “PHOTOLUMINESCENT MARKING WITH FUNCTIONAL LINING” (“PHOTOLUMINESCENT MARKINGS WITH FUNCTIONAL OVERLAYERS”), with a filing date of August 21, 2012; US Patent № 8,519,359 B2 at Kingsley and the other entitled "Stable to photolysis and in various media structure for highly efficient conversion of electromagnetic energy and sustainable secondary emission» ( «PHOTOLYTICALLY AND ENVIRONMENTALLY STABLE MULTILAYER STRUCTURE FOR HIGH EFFICIENCY ELECTROMAGNETIC ENERGY CONVERSION AND SUSTAINED SECONDARY EMISSION») , with the filing date of August 27, 2013; U.S. Patent No. 8,664,624 B2 to Kingsley et al., entitled “ILLUMINATION SUPPLY SYSTEM FOR SUSTAINABLE SECONDARY EMISSION” (“ILLUMINATION DELIVERY SYSTEM FOR GENERATING SUSTAINED SECONDARY EMISSION”), with a filing date of 4 March 2014 US Patent Publication No. 2012/0183677 on Agrawala and Others, entitled “PHOTOLUMINESCENT COMPOSITIONS, METHODS OF MANUFACTURE AND NEWEST APPLICATIONS” (“PHOTOLUMINESCENT COMPOSITIONS, METHODS OF MANUFACTURE AND NOVEL USES”), with a filing date of July 19, 2013 US Patent Publication No. 2014/0065442 A1 to Kingsley and Others, entitled “PHOTOLUMINESCENT OBJECTS” (“PHOTOLUMINESCENT OBJECTS”), filed on March 6, 2014; and US Patent Publication No. 2014/0103258 A1 on Agrawala and Others, entitled “COLOR LUMINESTER COMPOSITIONS AND TEXTILE PRODUCTS” (“CHROMIC LUMINESCENT COMPOSITIONS AND TEXTILES”), filed on April 17, 2014, all of which are included in this application by reference in its entirety.

The light source 62 may also be considered as an excitation source and is operable to emit at least the first radiation 28. The light source 62 may contain any form of light source, for example, halogen lighting, fluorescent lighting, light emitting diodes (LEDs), organic LEDs (OLED), polymer LEDs (PLED) and solid-state lighting or any other form of lighting made with the ability to output the first radiation 28. The first radiation 28 from the first source 62 of light can be configured from i so that the first wavelength corresponds to at least one absorption wavelength of one or more photoluminescent materials of energy conversion layer 44 and / or polymer matrix 50. In response to receiving light at the first wavelength, energy conversion layer 44 can be excited and output one or more output wavelengths, for example, the second radiation 30, having a second wavelength λ ₂ . The first radiation 28 may produce an excitation source for the energy conversion layer 44, aiming at the absorption wavelengths of the particular photoluminescent material or its combination used in it. As such, the lighting device 14 may be configured to output the second radiation 30 to form the desired intensity and color of the light.

In an exemplary implementation, the light source 62 comprises LEDs configured to emit a first wavelength, which may correspond to a blue spectrum, a violet and / or ultraviolet color range. The color range of the blue spectrum contains a range of wavelengths, generally expressed as blue light (~ 440-500 nm). In some implementations, the first wavelength may contain a wavelength in the ultraviolet or near ultraviolet color range (~ 100-450 nm). In an exemplary implementation, the first wavelength may be approximately equal to 470 nm. Although specific wavelengths and wavelength ranges are discussed with respect to the first wavelength, the first wavelength can generally be configured to excite any photoluminescent material.

In an exemplary implementation, the first wavelength may be less than about 500 nm. The color range of the blue spectrum and shorter wavelengths can be used as an excitation source for the illumination device 14 due to these wavelengths having limited perceptual sharpness in the visible spectrum of the human eye. By using shorter wavelengths λ ₁ and converting the first wavelength by a conversion layer 44 to at least one large wavelength, the lighting device 14 creates a visual effect of light arising from the photoluminescent structure 42.

As discussed herein, each of a plurality of wavelengths corresponding to the second radiation 30 may correspond to a significantly different spectral color range. The second wavelength may correspond to a plurality of wavelengths configured to appear as substantially white light. Multiple wavelengths can be formed by a red-emitting photoluminescent material having a wavelength of approximately 620-750 nm, an emitting green radiation of a photoluminescent material having a wavelength of approximately 526-606 nm, and emitting a blue or blue-green radiation by a photoluminescent material having a wavelength of greater than the first wavelength, and approximately 430-525 nm, in one of the embodiments. A variety of wavelengths can be used to form a wide variety of light colors from the photoluminescent portion 26 converted from the first wavelength.

FIG. 4 is a graphical image 70 of an exemplary radiation 72 of light corresponding to the first radiation 28, which is shown showing the wavelength relative to the direct current supplied to the source 62 of the light. FIG. 5 is a graphical image 80 of the absorbance of an input wavelength 82 of light (for example, the first radiation 28) relative to the fluorescence of the output wavelength 84 (for example, the second radiation 30) of an approximate photoluminescence portion. Referring to FIG. 4 and 5, the lighting device 14 may be operable to adjust the first wavelength of the first radiation 28 by adjusting the current supplied to the light source 62. For example, with a relative turn on time of 100%, as the forward current supplied to the first light source 62 rises from 20 mA to 170 mA, the first wavelength of the first radiation 28 changes from approximately 468 nm to 462.5 nm. By adjusting the forward current supplied to the first light source 62, the lighting device 14 may be operative to selectively adjust the wavelength corresponding to the first radiation 28.

In some implementations, the first wavelength of the first radiation 28 can be tuned by using a different type of light source and / or by adjusting the relative duration of switching on the light source 62. For example, as shown in FIG. 4, the operating range of the forward current of the light source 62 may vary from approximately 1 mA to 180 mA with a relative on-time of 100%. However, the operating range of the forward current of the light source 62 may vary from approximately 1 mA to 350 mA with a relative on time duration of 10%. In accordance with the increased range in the forward current range with a relative on-time duration of 10%, the first wavelength can vary from approximately 468 nm to 450 nm. In some implementations, the first wavelength can vary from approximately 468 nm to 462 nm. In an exemplary implementation, the first wavelength may vary by from 1% to approximately 3% in response to the setting of the direct driving current and the relative duration of switching on the first source 62 of light. Although specific ranges and values corresponding to the first wavelength, driver current, and relative turn-on duration are discussed in the materials of this application, specific ranges and values may vary based on the specific type of light source, for example, different blue LEDs.

By adjusting the first wavelength of the first radiation 28, the lighting device 14 may be operable to adjust the first radiation 28, such that the first wavelength corresponds to a different level of absorbance of the input wavelength 82 of the photoluminescent part 26. In accordance with an example discussed with respect to FIG. 4, the first wavelength can be adjusted from about 468 nm to 460 nm. As shown in FIG. 5, the absorbance level of the photoluminescent portion 26 can vary from approximately 0.78 to 468 nm at point A to 0.6 at 460 nm at point B. Essentially, the photoluminescent part 26 can absorb a smaller part of the first radiation 28 when the first length The wavelength is approximately 468 nm than when the first wavelength is approximately 460 nm. By adjusting the first wavelength, the conversion bandwidth of the photoluminescent portion 26 can be adjusted so that the color of the emitted light 32 is changed.

The ability to convert the photoluminescent part can correspond to the magnitude or speed with which the photoluminescent part 26 can be operative to convert light energy from the first radiation 28 to the second radiation 30. By controlling the first wavelength, the conversion ability of the photoluminescent part 26 can be adjusted, so that the lighting device 14 could be effective for adjusting the color of the emitted light 32 by adjusting the forward current supplied to the light source 62. In this configuration, the lighting device 14 may be operable to mix the colors of the first radiation 28 and the second radiation 30. Thus, the lighting device 14 may be configured to control the first radiation 28 with the first intensity to output the second radiation 30 in a ceiling light configuration, corresponding to the first color, and control the first radiation 28 with a second intensity to output the second radiation 30 in the read light configuration corresponding to the second color.

The first state, as discussed herein, may correspond to the function of the ceiling light of the lighting device 14, and the second state may correspond to the function of the reading light. The first state may be activated by the lighting controller of the vehicle 12 in response to a plurality of vehicle states. For example, the first state may be triggered by the lighting controller in response to the opening of the door of the vehicle 12, and different time periods corresponding to the entry and exit periods of the vehicle 12. The second state may be selectively activated by the lighting device in response to the input signal one or more switches 18. As such, the lighting device 14 may provide general purpose lighting and local lighting to illuminate the vehicle 12.

Next, with reference to FIG. 6, a diagram of the lighting device 14 according to one of the implementations is shown. In order to diffuse the light emitted from the light source 62, the diffuser optics 92 may be located closer to the light source 62. The diffusing optics 92 may form a cavity configured to receive the first radiation 28. The diffusing optics 92 may correspond to a first portion of a molded polymeric material forming the outer edge of the optical device 64. The optical device 64 may correspond to a second portion of the molded polymeric material.

The optical device 64 may be configured to receive the first radiation 28. The material of the optical device 64 may contain photoluminescent material of the photoluminescent portion 26 located therein. As the first radiation 28 is transmitted through the photoluminescent part 26, the first radiation 28 can be converted to the second radiation 30. A part of the second radiation 30 can additionally be transferred from the optical device 64 to the light-diffusing optics 92. In this configuration, the light-scattering optics 92 can be performed with the ability to emit diffused radiant light on the outer surface 94 of the lighting device 14, and the optical device 64 may be operable to emit directional light from the projecting the light of the surface 96 of the lighting device 14. Each of the diffused radiant light and the directional light may correspond to the emitted light 32.

Next, with reference to FIG. 7, in some implementations, the lighting device 14 may contain a reflective coating 102, for example, a metal coating located on the outer surface of the optical device 64. In this configuration, the first radiation 28 can be converted to a second radiation 30 due to the excitation of the photoluminescent material of the photoluminescent part 26. Additionally, the first radiation 28 and the second radiation 30 can be reflected to the optical device 64 with a reflective coating to ensure that the emitted light 32 is directed to the outside through the projecting surface 96. In this configuration, the lighting device 14 may be configured to output substantially all of the emitted light 32 through the projection surface 96 to provide improved projection of the emitted light 32.

Next, with reference to FIG. 8, in some implementations, the photoluminescent portion 26 may be located in a light converting optical device 112. The light converting light optical device 112 may correspond to an optical glass or at least partially a translucent part located closer to the light source 62. The light converting optical device 112 may contain photoluminescent material of the photoluminescent part 26. In this configuration, the first radiation 28 may be output from the light source 62 and into the light converting optical device 112. In response to receiving the first radiation 28, the photoluminescent material may be configured to convert at least part of the first radiation 28 to the second radiation 30. The second radiation 30 and part of the first radiation 28 can then be transmitted from the optical device 64 converts the light of the optical device 112 In this configuration, the optical device 64 may correspond to a transparent polymeric material capable of transmitting the second radiation 30 and part of the first radiation 28 through it. The second radiation 30 and a portion of the first radiation 28 can then be output as the emitted light 32 from the light projecting surface 96.

The disclosure provides a vehicle lighting device configured to highlight at least a portion of the passenger compartment. The lighting system may be configured to operate in at least the first state and the second state. The first state may correspond to a ceiling light function configured to emit light from the illumination device, which is essentially white, having a warm shade. The second state may correspond to the function of light for reading, made with the ability to emit light from the lighting device, which is essentially white, having a cool shade. Light corresponding to the second state may also have an increased intensity relative to the emitted light in the first state. Thus, the lighting device can be configured to highlight the passenger compartment of the vehicle in a shade of white light that is best adapted to the specific activity of the passenger or driver.

It should be understood that changes and modifications may be made to the above construction without departing from the concepts of the present invention, and in addition, it should be understood that such concepts are intended to be covered by the following claims, unless this formula explicitly states otherwise. .

Claims (26)

1. A vehicle lighting device comprising: monochromatic light source made with the possibility of emitting the first radiation of the first color in the blue spectral range and associated with the controller, while the first color is made with the ability to excite the photoluminescent part to emit white light, while the controller is configured to adjust the output color of the second radiation output from the photoluminescent part, by setting the direct driving current and the relative duration of the monochrome light source so that the intensity of o radiation exceeds the conversion ability of the photoluminescent part. 2. The lighting device of claim 1, wherein the white light is adjusted to include an increased fraction of the first color in response to an increase in the intensity of the first radiation. 3. The lighting device according to claim 2, wherein an increased proportion of the first color corresponds to a higher proportion of blue in the output color. 4. The lighting device according to claim 2, wherein the output color changes from warm white to cool white in response to an increase in the intensity of the first radiation. 5. The lighting device according to claim 1, wherein the controller additionally functions with the possibility of increasing the proportion of blue light in the output color by increasing the intensity of the light output. 6. The lighting device according to claim 1, wherein the controller further functions to adjust the intensity of the first radiation in response to an input signal from one or more switches connected to the controller and in response to a change in intensity, the output radiation changes from warm white to white light with a cool blue tint. 7. Vehicle lighting device comprising: monochrome light source, made with the ability to emit the first radiation of blue color; an optical device containing a photoluminescent part, made with the ability to convert at least part of the first radiation into the second radiation of essentially white color; light scattering optics containing an annular groove located along the outer edge of the optical device, and a controller configured to adjust the color of the second radiation by selectively adjusting the intensity of the first radiation. 8. The lighting device according to claim 7, wherein the first radiation and the second radiation are mixed to form an output color comprising the first color in the first state and the second color in the second state. 9. The lighting device according to claim 8, wherein the first radiation in the first state corresponds to a lower light intensity than the first radiation in the second state. 10. The lighting device according to claim 8, wherein the second color contains a higher proportion of blue hue than the first color. 11. The lighting device according to claim 8, wherein the lighting device is configured to emit the output color as warm white light in the first state and cold white light in the second state. 12. The lighting device according to claim 8, wherein the photoluminescent portion corresponds to a photoluminescent material located in the optical device substantially aligned with the light source. 13. The lighting device according to claim 12, further comprising a light scattering optics located along the outer edge of the optical device, the optical device being configured to transmit the second radiation to the light scattering optics. 14. The lighting device according to claim 13, wherein the light scattering optics are configured to emit a second radiation as scattered radiant light on the outer surface of the lighting device and the optical device is configured to emit a second radiation from the light projecting surface of the lighting device. 15. The lighting device according to claim 7, wherein the color setting of the second radiation is a result of the intensity of the first radiation exceeding the conversion ability of the photoluminescent part. 16. The lighting device for the vehicle, containing: a light source associated with the controller and configured to emit the first radiation; an optical device comprising a photoluminescent part configured to convert at least a part of the first radiation into a second radiation, and an annular light scattering optics located around the optical device, the optical device being configured to transmit the second radiation to the light scattering optics, while the controller is configured with opportunity: control the first radiation with the first intensity in order to output the second radiation in the ceiling lighting configuration corresponding to the first color; and control the first radiation with the second intensity to output the second radiation in the read light configuration corresponding to the second color, wherein the change from the first color to the second color is performed in response to the second intensity exceeding the conversion ability of the photoluminescent part. 17. The lighting device according to claim 16, wherein the first radiation is emitted with a first intensity corresponding to the configuration of the ceiling light and a second intensity corresponding to the configuration of the reading light. 18. The lighting device according to claim 17, in which the second intensity is greater than the first intensity. 19. The lighting device according to claim 16, wherein the second color contains a higher proportion of blue hue than the first color.

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