TR201601435A2 - PHOTOLUMINESE VEHICLE COMPARTMENT LIGHT - Google Patents

Abstract

A lighting system for a vehicle is disclosed. The system comprises a photoluminescent portion disposed on an inner surface of a lid of a chamber. A light source is located near the cover. The light source is configured to emit a drive emission at a first wavelength directed towards the photoluminescent portion. The photoluminescent portions are configured to convert the first wavelength to at least one second wavelength longer than the first wavelength.

Description

DESCRIPTION PHOTOLUMINANCED CAR COMPARTMENT LIGHT Reference to the relevant application] This reference is "VEHICLE LIGHTING SYSTEM WITH PHOTOLUMINESCENT STRUCTURE. continuationIIB The relevant reference cited above is incorporated herein by reference in its entirety. has been made.

Technical Field of the Invention The present invention includes vehicle lighting systems in general and photoluminescent systems in particular. It is related to the vehicle lighting systems used in the structures.

State of the Art of the Invention (Prior Art) Illumination from photoluminescent materials gives an original and attractive appearance. gives experience. Therefore, we use tools to provide environment and task illumination. It is desirable to include these photoluminescent materials with k-ilarl.

Find out Klâia Açtlilamaslîl According to another aspect of the present invention, a lighting system for a vehicle The system being opened is a cover placed on an inner surface of a compartment. photoluminescent clgin. A @El resource has been placed on the cover. IsllZl The source is an excitation at a first wavelength directed towards the photoluminescent coil. It was made in a way to emit emission, by converting it to at least one second wavelength longer than the first wavelength madellândlEllBIIIstE According to another aspect of the present invention, a lighting for a compartment of an instrument the system is being opened The system is equipped with at least one cover, one of which is placed on an inner surface. consists of photoluminescent light. the source is placed. IslIZl sourceZi to emit @Ki at a first wavelength YapllândlElIJB Photoluminescent k-illar first wavelength, to brighten the compartments, first by converting it to at least one second wavelength longer than the wavelength yapllândlüllmlîstlîl According to another aspect of the present invention, a lighting for a compartment of an instrument the system is being explainedIE The system is composed of at least one cover, one of which is placed on an inner surface. consists of photoluminescent k-idan. the source is placed. Emitting @El at a first wavelength with heat source YapilândlElmîl Photoluminescent cellar uses the first wavelength, the second wavelength relative to the compartment will emit and convert to at least one second wavelength longer than the first wavelength. done in this way These and other aspects of the present specification, its purposes/features, the following specification, be understood by the person skilled in the art after examining the claims and accompanying figures. and can be appreciated.

Opening Figures In figures; Figure 1 is a vehicle consisting of a lighting system. is a perspective view; Figure 2A is a side view of a photoluminescent build-I supplied as a coating. shows, Figure ZB is a side of a photoluminescent artifact delivered as a separate particle. shows the view, Figure 2C shows the multiplexes given as separate parts and included in a separateZ structure. photoluminescent structureII is an edge view, Figure 3 is configured to convert a first related emission to a second emission. demonstrates a vehicle lighting system Figure 4 is to convert a first ls-imission to multiple @Elemissions. builtlEliBilS demonstrates a vehicle lighting system Figure 5, a powerful lighting designed to illuminate an engine compartment a vehicle with a system. is a perspective view; Figure 6 illuminates at least one engine component in an engine compartment. YapllândlEllEuSlA vehicle with an illuminated lighting system. is a perspective view; Figure 7, a tool. a cover light.. has a built-in lighting system a vehicle. is a perspective view, Figure 8 shows a canopy that can be applied as a retractable or retractable sign. A vehicle with a lighting system that includes is a perspective view, Figure 9 shows a lighting system with an adjustable lHand transmission device. tool& is a perspective view; Figure 10 shows a minimum of built to selectively illuminate a feature and with a vehicle control module with a block diagram of a communicating lighting system Distinguishing the Invention Available as needed However, the structures that have been opened in the future can only be found in different/alternative forms. They are in the nature of examples that can be done. Separation of shapes is mandatory without a single design. is not, and some diagrams can be exaggerated or exaggerated to show the function overview. can be reduced. Therefore, the specific structural and functional details explained here are silEIiandIElEIZl. should be interpreted as a representative basis, not as It is a guide to the person skilled in the art to implement it.

As used herein, the term "and/or" refers to a list containing two or more items. Use the single press of any of the items listed. available or listed Two or more of the elements makes sense that any combination of EllEl can be used. is coming. For example, if a composition is described as containing components A, B and/or C If it is being used, the composition is a single bass. Press A'yCal. B, one press. C, A and B together, A and C may contain B and C together, or A, B and C together.

Downward opening shall be such that at least one side of an engine compartment is illuminated. YapliândlEllEnlgl describes a lighting system for a vehicle. In some applications, a lglKlkaynagElbir functional @gb karsilIlZl in a way that will generate a first photoluminescent klginlgyd it can be done. At least one engine compartment feature as a heat source, component, slîEreservoirZl/e / or any other vehicle located near the engine compartment. It can be made to illuminate a second photoluminescent use. In different/apllândlunas, the first photoluminescent k-made to illuminate the engine compartment It may come up against the lighting unit. The second photoluminescent k-i covers at least one engine compartment. It may correspond to an additional lighting unit if it is made to illuminate.

Referring to Figure 1, at least one klgfnIEl of an engine compartment (14) A vehicle (10) showing a relevant lighting system (12) constructed to illuminate perspective view is shown. The lighting system (12) is placed on the inner surface of the hood (18). (17) an embedded @El source (16) and at least one photoluminescent glow (20) formingdlE as discussed here, to close the tool yapllândlîllüîlg corresponds to a cap or a cap. Samples made on hands, cover (18) a competent vehicle constructed to contain an engine compartment and/or tailgate a large rear trunk lid designed to cover the hood/or a cargo compartment can express. In BazliyapllândlElnas, the cover (18) is a tool. against a doorhand/or cap may come.

In BazEl/apilandlElnas, at least one photoluminescent k-i (20) is more than one photoluminescent k-idan (22) may occur. IsEsourceEdlö), a DIE corresponding to a first wavelength Constructed to OUTPUT to first emission (24) in response, multiple photoluminescent k. (22) illuminable and from the first wavelength emit at least one second emission 26 having a longer second wavelength.

More than one photoluminescent k-i (22) located in the engine compartment (14) and at least one make photoluminescent, any number of features placed on the inner surface (17) KarsÜJE may come. An example was made by Emada, the lighting system (12) with a first photoluminescent k. (28) and a second photoluminescent k-idan (30) (28) to emit a high-density ligh to brighten the engine compartment (14). A function related to donellândIEllB may correspond to Sigi- (32). Second photoluminescent k. (30) engine It may correspond to at least one feature (34) in the pane. Second photoluminescent k-i (30) to provide an ambient glow from at least one feature (34) It can be done in a way that will make it clear.

Multiple photoluminescent channels (22) each in response to the first emission (24). Constructed to emit a specific color in response to the stimulation produced It may contain too much photoluminescence. In some DyapilândlEinas, a photoluminescent structure using the combination of photoluminescent lights (22) corresponding to different EEKl colors. can be obtained with different wavelengths. For example, in some El/apuandliilnas, the function EgiE(32) is immediately used to produce an Eig with an immediate white appearance, green EiZl and blue Egil It can be made to spread a combination of The lighting system (12) is an engine of the engine compartment (14) comprising a cost-effective method of illuminating the Approximately can provide different months of months that contain at least one feature (34) setting the environment.

Referring to Figures 2A - 2C, a tool capable of being applied to a vehicle fixture The coating (eg, a film) is a separate[El] capable of being implanted into a vehicle fixture. particle, and a separate/application capable of being applied to a vehicle fixture is included there is a photoluminescent structure (42) shown as more than one separate particle. Photoluminescent structure(42) eg first photoluminescent k-i (28) and second photoluminescent Like k-i (30), it may correspond to the photoluminescent k-ilara discussed here. the most basic At the level, the photoluminescent structureE(42) is shown as sharp lines in Figures 2A and ZB. an energy conversion that can be provided as a single layer or a multi-layer structure. It contains layered[(314).

The energy conversion layer(44) is made of a photoluminescent or a fluorescent material. selected energy conversion elements. one or more photoluminescent materials may contain. Photoluminescent materials usually emit electromagnetic radiation entered electromagnetic radiation with a longer wavelength than electromagnetic radiation and to electromagnetic radiation that gives a color uncharacteristic of the radiation can be formulated to transform Incoming and outgoing electromagnetic radiations difference in wavelength between them. Stokes slips/melts and this is usually a downturn An energy conversion corresponding to a change in Egil wavelength, designated as It functions as a principle drive mechanism for the process. Here's the difference that's allEmE discussed] Conversion of each of the EglEl wavelengths (eg first wavelength etc.) It corresponds to electromagnetic radiation used in the process.

Photoluminescent clays each consist of at least one energy-converting layer. A photoluminescent 42 may occur (eg, the transform layer E(44)). energy conversion layerE(44) is used to create a homogeneous square using many different methods. This is prepared by dispersing the photoluminescent substance in the polymer matrix (50). energy conversion from a formulation in an intermodal environment layerII (44) preparationElve energy conversion layerEI (44) of a tool fixture a desired planar and/or non-planar substrate-coating. Energy transform layerHand(44)coating,painting,screen scale:spraying,slot coating, daldunal plating can be placed on a tool fixture with cylinder plating and rod plating.

In addition, energy conversion with methods that do not use a sulîltaslglîlîlortamllîl layerEa44) can be prepared. For example, a solution of admixture of one or more photoluminescent materials (a a polymer to provide a homogeneous mixture in the dry state) energy conversion layer E444) may be included in the matrix (50). Polymer matrix (50) extrusion, injection molding compression calcination, calendering, handforming etc. can be created with one or more Where the excess energy conversion layer II (44) is delivered as particles, single or multiple layered energy conversion layers (44) can be implanted in a vehicle fixture or panel.

Where the energy conversion layerE(44) contains many layers of Eformulation, each The layer can be easily coated. In addition, layers can be prepared separately. and can then be laminated together to form an integral layer or can be embossed. Layers at the same time make an integrated multi-layer energy conversionIEEI It can be pulled together from the mold in a way that will be prepared.

Refer to Figures 2A and ZB, Etla, photoluminescent (42) energy conversion layer] (44) to protect the photoluminescent material contained in it from photolytic and thermal degradation. for at least one stability layer EI 46 . Stability layerEl(46) energy conversion layer. It can be constructed as an optically coupled and structured separate layer.

The stability layer E(46) can be integrated with the energy conversion layer [44] in separation.

Photoluminescent structure(42) at the same time photoluminescent structureTLIZ(42) from environmental exposure stability layer to protect it from physical and chemical damage caused by (46) or optically coupled or bonded to any layer or coating layer 48).

The stability layer (46) and/or the protective layer (48) simultaneously provides energy. Each layer combined with the transform layerE(44). leilCoatingElieya bastlEIlBiasEl or an integrated photoluminescent structure42) can be formed by thermal lamination or embossing.

Alternatively, coating, laminating or embossing to create a substrate can be combined with The substructure is then formed to form the integrated photoluminescent structure(42). can be laminated or embossed. Photoluminescent when created42) a selected vehicle applicable to the fixture.

In some U/Apllândulnas, the photoluminescent structure(42) is one or more more separators can be incorporated into a tool fixture as multi-layered barticula. photoluminescent structure(42) one or more separators embedded in a polymer formulation at the same time can be provided as multi-layered particles, and this can then be done as a continuation as a tool Can be applied to fixture or panel. A vehicle will be used with at least one photoluminescent light Additional information on “photoluminescent structures”, submitted on July 32, 2012 “HIGH EFFICIENCY ELECTROMAGNETIC ENERGY CONVERSION AND PHOTOLIC AND ENVIRONMENTALLY STABLE SOFTWARE FOR SUSTAINABLE SECONDARY EMISSIONS LAYERED STRUCTURE” in US Patent 8,232,533 issued to titled "ZlEKingsley" et al. openZlanmlStE Referring to Figure 3,[g]there is a first coming from the lighting system (12) related sources (16). a pre-illuminatedEconfiguration to convert the emission (24) to a second emission (26) shown accordingly. The first emission 24 consists of a first wavelength A1 and a second The emission (26) consists of a second wavelength (A2). The lighting system (12) consists of a a substrate (68) applied as a coating and a tool fixture (70) may contain photoluminescent fiber(42). Make photoluminescent(42) an energy conversion layerEl (44) and/or a protective layer (48) with a stability layer on the bases. may contain. The first emission (24) in response to the activation of the heat source.. the first wave from wavelength A1 is converted to the second emission 26 having at least the second wavelength A2.

Second emission (26) from vehicle fixture (70) to emit almost white [row A2, A3, A4 may occur from more than one wavelength.

In different/applications, the lighting system (12) uses the A1 first wavelength at the first wavelength. in such a way as to convert the emission to the second emission (26) having at least the second wavelength A2. A little energy conversion layer moment (44) is formed. More than one wavelength To produce A2, A3, A4, the energy conversion layer [(44) is embedded in the polymer matrix (50) a klinlîIZl/ayan photoluminescent substance, a green-emitting photoluminescent substance, and a blue may consist of emitting photoluminescent material. Photoluminescent emitting Klîilnlî in green and blue substances can be combined to produce an almost white @El for the second emission (26). Ayrlila, Colorless and blue-emitting photoluminescent substances control the color of the second emission (26). It can be used in different forces and combinations to

Each of the photoluminescent materials uses an energy conversion layer (44). combinations of photochemical structures based on a specific photochemical making Intensity, wavelength and peak absorption wavelengths may differ. A for example, the second emission (26) can be changed to change the color of the second emission (26) waveform of the first emission (A1) to activate photoluminescent materials at high intensities. can be changed by adjusting the height. KIELnIîIZI green and blue @El emitting photoluminescent to produce the second emission (26) in various colors, in addition to or as an alternative to the materials a single press for the purpose. or other photoluminescent materials in different combinations. usable. In this way, the lighting system (12) will have the desired lighting color and color for the vehicle (10). It can be made for various applications to give an effect. it can be operated to emit the first emission (24). Is[lg sourceE(16) any other @Ki sources, eg halogen lighting, fluorescent lighting, @Ki emitting diodes (LED), organic LEDs (OLEDs), polymer LEDs (PLEDs), floor lighting or primary from any other form of illumination configured to give the emission (24) may occur. The first emission (24) from the thermal source (16) can be made in such a way that the first wavelength (A1) energy conversion layerIE (44) one or more photoluminescent corresponds to at least one absorption wavelength of the material. A1 lgIKl at first wavelength In response to receiving, the energy conversion layer E044) is driven by one or more It can emit wavelength A2, A3, A4. The first emission (24) used there is the differenceIEphotoluminescent energy conversion layer by targeting absorption wavelengths of materialsE(44) a drive source for the tags. In this way, the lighting system (12) gets the desired light intensity and Constructed to allow second emission (26) to produce color Although wavelengths are expressed as A2, A3, A4 wavelengths, In addition, photoluminescent materials are intended to produce color variants for the second emission 66. It can be combined into different types, types, layers, etc. Photoluminescent materials mirror hand At the same time, for example, a third emission, a fourth emission, etc. any saylîzlh like more than one dispersed along a path of the first emission (24) producing emissions. photoluminescent light can be used. Third emission second photoluminescent k-idan (30) a third photoluminescent located on the springable and fourth emission means 10 k-idan can spread.

Once an example has been made, the EE source(16) is opposed to a blue spectral color range. It consists of an LED configured to emit the incoming first wavelength A1. Blue The spectral color range consists of a range of wavelengths commonly referred to as blue EE. ((~440-500 nm). In BazEyapllândEnas, the first wavelength A1 is at the same time wavelengths may occur in the color range (~390-450 nm) close to an ultraviolet. Sample In yapliandluna, A1 may be equivalent to approx. 470 nm. BazEyapUândlElnada, first wave length may be lower than A1 500 mm, such that Egil first wavelength almost invisible.

Blue spectral color range and shorter wavelengths in the visible spectrum of the eye, depending on the acuity It can be used as a drive source for the lighting system (12). For first wavelength A1 more kea wavelengthshand use and convert layerEa(44) to the first wavelength lighting system (12) by converting to at least one longer wavelength The Egil resulting from the photoluminescent structure 42 creates a visual effect. This In this configuration, the vehicle (10) is inaccessible or requires conventional electrical connections. Where adding EE sourcesE1 is costly, EE welds (42) (eg. one photoluminescent k-i (28), the second photoluminescent k-i (30) EEyayliiEl As explained here, multiple wavelengths (A2, A3, A4) differ significantly. It may oppose the spectral color range[1]. Second wavelength A2 approx. 620- 750 nm wave length may correspond to the propulsion of photoluminescent material. Third A green-emitting photoluminescent with a wavelength of A2 approx. 526-606 nm It may come against the propulsion of the material. The fourth wavelength is A4 and the first wavelength is A1. a blue or blue with a longer wavelength, about 430 to 525 nm It may oppose green-emitting photoluminescent material[l]. Although the wavelengths are EAZ, A3, A4 although it is used here to produce an almost white IE, difference of photoluminescent materialCombinations of transforming layersEtia (44) first wave will convert the wavelength (A1 ) to one or more wavelengths corresponding to the difference[1]colors. can be used in

Referring to Figure 4EUa, the EE system (12) in a front-lit configuration is shown. In one example application, EE source(16) is more than one photoluminescent. The kEna(82) may be configured to emit the correct first emission 24. In this example, one excess k-(22) first photoluminescent k-idan (28), second photoluminescent k-idan (30), and the third photoluminescent k-idan (84) consists of each Photoluminescent k-illar (28, 30, 84) one is the first wavelength (A1) of the first emission (24) from more than one wavelength (A2, A3, A4) can be made to convert one or more of them. In this way, the first emission (24) Photoluminescent uses (82) to reveal a multi-colored lSlElandlîilna effect can be converted to more than one emission from each. For example, the first photoluminescent k- (28) will produce the second emission (26). A transforming layer-a-build made up of photoluminescent materials. Second The photoluminescent k-i (30) is configured to produce a third emission (86). The transforming layer may consist of two photoluminescent materials. Third photoluminescent k-i (84) can be configured to produce a fourth emission (86) The layer may consist of photoluminescent materials. With reference to Figure 3, allEtnlgl is discussed energy conversion layer. (44) in a similar way, to emit water in different colors. Yapllândlîllüilglphotoluminescent materials are responsible for the second emission (66), the third emission (86) and different Eloranes and can be used in combinations. Based on the desired moon Elama effect, emissions (26, 86, 88) each with almost the same colors or combinations of colors. It may consist of EllEnlSlphotoluminescent material made to diffuse.

The different colors and colors of the photoluminescent materials described herein In order to achieve combinations, the illumination system (12) must not contain any phospholuminescent material form, eg phospholuminescent materials, organic and inorganic dyes etc. can use. Production of photoluminescent materials to achieve differential emissions and For additional information on use, see the lower springs. "PHOTOLUMINANCES FIBERS, COMPOSITIONS", applied for on June 26, 2012 AND FABRICS MANUFACTURED FROM THEM” by Bortz et al. given PHOTOLUMINANCES SIGNS WITH LAYERS” basiuaüAgrawai et al- “HIGH EFFICIENCY ELECTROMAGNETIC ENERGY CONVERSION AND SUSTAINABLE PHOTOLIC AND ENVIRONMENTALLY STABLE MULTILAYER STRUCTURE FOR SECONDARY EMISSION" “TO PRODUCE SUSTAINABLE SECONDARY EMISSIONS”, which was applied for LIGHTING TRANSMISSION SYSTEM U.S. Patent No. 11, “PHOTOLUMINASAN, filed on July 19, 2012 COMPOSITIONS, MANUFACTURING METHODS AND INNOVATIVE USES” titled "Compositions," and “PHOTOLUMINESANC OBJECTS” application for baslllZlEKingsley et al. given 17mm. 04aaa. "CHROMIC LUMINANCES COMPOSITIONS AND Patent Yaylüve Them OK [included herein by reference in their entirety.

Referring to Figures 5 and 6, the vehicle showing multiple photoluminescent terminals(22) (10) the engine compartment (14) is shown. The hungrier is placed on the inner surface (17) first photoluminescent k. (28) is shown with reference to Figure 5 and multiple photoluminescent lamps located in the engine compartment (14). (82) in Figure 6 shown. Suraslîlanlasllîhalllîl photoluminescent cellar (82) which is discussed here any construction along the inner surface (17) of the hood (18) and the engine compartment (14) may be dagmßig. Considered here allEU[g]ES, the first photoluminescent k. (28) justified and as a function (32) to illuminate the engine compartment (14) for inspection it can be done. In response to placing the cap (18) in an angled position, the intermediary (10) it can be configured to activate a lighting control module @El sourceglElEKIG).

Also, in response to the activation of the light source (16), the first emission (24) first wave It can be activated in such a way as to make it relevant to having a length of A1. constructedlEllBiE can consist of more than one LED. BazElyapElândlElnalarda, @El welding(16) The cover (18) consists of a forward air conditioner (92) from an array of LEDs placed in close proximity. may occur. @Ekaynagîdlü by placing the isHZl sourceIEQIS) close to the forward klElna (92) Arac& (10) may experience a lower lye density in the Çallglnasßlâisü. For example, the cover (18) when placed in a closed position, lâllîlkaynaglîqlö) a radiator or cooling the source(16) can be placed approximately so that the relevant source(16) is an engine (10) A @Sömine coming from the chamber (14) will not be damaged.

As shown in Figure 5, ElElkaynagEQIG) nearly the first photoluminescent kgna (28) configured to direct the correct first emission (24) EllIhlgtE AyrlEla, the first emission (24) into the engine compartment (14) when the hood (18) is directed in an open position. can be oriented correctly downward/forward. For example, the water source) can be attached to the inner surface (17), such that the first emission is centrally focused on the engine compartment (14) can be steered immediately downstream. Welding and Welding ElJlö) one or more optics at the same time through the lens or device, towards the first photoluminescent chamber (28) and the engine compartment (14). it can be configured to direct the first emission (24). In this construction, the first wave length )\1 the first emission TIGHT weld (16) springs out the engine compartment (14) The first photoluminescent light (28) placed on the cover (18) to illuminate clarify immediately Although immediately between the first emission hood (18) and the engine compartment (14) Although it can be directed immediately through the angular volumetric field, the Egil is A1 at the first wavelength. enlightenmentEblglElal can be deleted. A1 sIEllEl of the first wavelength can be seen or A1 blue or near-UV spectral color of the detectable first wavelength It can be connected even if they are in their range. With such klêh wavelengths, the human eye's Elgh karslîl First emission lighting, depending on the light sensitivity (e.g. blue colored LIGHT) system (12) may not be noticed by the viewer. In this section, multiple photoluminescent lamps (22) each of which can be illuminated in 0 ways that photoluminescent lamps (22) The source of activation would not be powerful enough to provide a hash-lighting experience.

First wave of first emission (24) by first photoluminescent k-i (28) In response to the longitudinal A1 energy conversion layer [(44) can be driven and the second emission (26) can radiate. Like allEUlgll discussed earlier here, the second emission is a distinctive white @El More than one wavelength of A2, A3, A4 can be formed to produce Second emission (26) general directly to the engine compartment (14), such that multiple features (96) are illuminated. The photoluminescent lamp (28) configuration of function related (32) is single-sided across the engine compartment (14). The format can provide illumination.

Now look at Figure 6IEglia, first emission (24) lglElsource (16) down/ahead any number, directed towards the engine compartment (14). one of more than one feature (96) matrix (e.g. polymer matrix (50)) applied to and/or built into or more photoluminescent k-ida (82) can drive a transform layerIE(44). For example, a second photoluminescent k-i 30 may be fitted with an engine cover 98; third The photoluminescent k-84 can be incorporated into an air tube (100) and a support tower beam 102.

In response to receiving the first emission (24) from the first wavelength )\1, more than one Each of the photoluminescent lamps 82 can be driven. Propulsion Second photoluminescent ring (30) third emission (86) and third photoluminescent fraction (84) fourth emission (88) dissemination causes. The first photoluminescent air conditioner facing hungry (28) from KarsUJE differentiyrlEtllârESis shown in Figure 6.

Although multiple photoluminescent k. (82) special reference to three example kîlna Although it can be considered as more than one photoluminescent k. (82) other made according to lElna any number of the engine compartment at about hand. the air conditioner may come against it. More than one The photoluminescent portion (82) has many different colors, each in response to the first emission (24). Different energy containing different photoluminescent materials made to emit May contain transform layers. In this way, the lighting system (12) function lglg'llîl (32) shall provide and/or any number. feature (96) to highlight can be used in various settings.

Multiple features (96) engine compartment (14) and cover (18) yakEIa in general may consist of any feature associated with the inserted tool (10). Multiple features (96) any of which is applied as a coating and/or the first wave of the first emission (24) a material embedded in a material that can emit EUZJ in response to taking size A1 May contain photoluminescent. Photoluminescent colors (82) each with a single color or multiple it can be illuminated as more than one color and thus to illuminate more than one feature )94) A desired color palette and appearance can be provided. Photoluminescent lights (82) at the same time One or more features (94) for easy identification can be used for identification.

On the baseEyapllândElnas, the cylinder fill cap(104), oil dipstick or other at least one of any feature (94) is an emission consisting of a diagnostic color (eg. third emission (86), fourth emission (88)) photoluminescence (42) may occur. Diagnosed, first emission (24) of feature (94) it can spread as a response. A diagnostic tool It can be made to correspond to a color described in the instructions. BaseHand In yapllândlîilnas, more than one photoluminescent k-i (82) has a first color with a second color. identifying a first feature having a first color that is visually distinguishable from feature 108, Against more than one diagnosis made to categorize and/or provide]K| may come. In this way, the lighting system detects the difference between the engine compartment (14) and decorative lighting that can serve as an aid in diagnosis can provide additional functionality.

Now look at Figure 7[g]I, a tool. (124) a capglilule (122) approx. A lighting system 120 is shown as installed. Bazliyapllândülnas, cover (122) may correspond to a vehicle hood or a tailgate for a vehicle body.

The lighting system 120 may include elements and features similar to the lighting system 12 .

The lighting system 120 is a vehicle control module and/or a user interface, for example a It may contain a controller communicating with the human machine interface (HMI). vehicle control module or in response to an input received from the user interface, the controller may operate to open the cover (122). an inner surface (selectively ayd-atm As shown in Figure 7, a photoluminescent k- interior surface 127 bonded to a can be placed on the hood insulator. Similar to the lighting system (12), the lighting system (120) dlSlklgnlEl (131) at least one lgllîlsource (130) placed approx. a drive emission from the access zone of the vehicle compartment, for example an engine compartment (132) it can be illuminated by spreading it.

In some APs, at least one photoluminescent k-i (126) is a first photoluminescent k-i 126a and a second photoluminescent k-i 126b. As shown in Figure 7, first photoluminescent k-i (126a) is a useful Egl- (134) kars[[[Kl can come home second photoluminescent k-i (126b) may correspond to a graph (135). Graphic (135) to letters, may refer to symbols, shapes, designs, or any other graphic format. A The example is built on hand, graphic (135) can be selectively displayed by the controller in an emergency. A problem message that can be activated may occur against Ela.

At least one EEKaynagEQBO) a first @Ekaynaglüa (130a) and a second ElKlkaynag- selective to give at least one emission of streaks from one of the second photoluminescent lights 126b can be activated. The thermal sources II (130a and 130b) each have a first arcEE and a second spring-n may occur. First spring to output a first drive emission (128a) can be made it can be done. Propulsion emissions II (128a, 128b) each, slurry first photoluminescent one or more embedded in the k-i 126a and the second photoluminescent k-i 126b The photoluminescent material may correspond to an absorption range[l]]Zl. In this construction, illuminance system (120) first photoluminescent klgrnlîuzöa and second photoluminescent klglnlîl (126b) can be played in a way that makes it clear almost depending on the subject.

Photoluminescent glows (126a, 126b) are almost independently To illuminate, the corresponding energy conversion layersEisEla first The propulsion emission (128a) and the second drive emission (128b) are mixed along one wave. It can be configured to have future propulsion absorption ranges. For example, specific photoluminescent materials can be selected in such a way that photoluminescent k- (126a) approximateZl 480 Photoluminescence consisting of a first peak absorption with a wavelength of nm materials can be selected in such a way that the second photoluminescent k-i (126b) approach It consists of a second peak absorption at a wavelength of 440 nm. system (132) first photoluminescent klgmlîl126a and second photoluminescent klgh'ilîl126b) immediately it can work in a way that will immediately illuminate it. Although 440 nm and 480 nm Although specific wavelengths are discussed with reference to current practice, surasllnlasilJ-:halllîl Photoluminescent materials, photoluminescent k-IIIs (126) with two different amylum ranges It can be used to adjust the absorption ranges.

The SpringHands each have either the first drive emission (128a) or the second drive emission. (128b) configured to emit selectively Handle First drive emission (128a) approx.480 A nearly aligned ISlWwave with a first peak absorption at a wavelength of nm it can be made in such a way that it spreads in length. The second drive emission (128b) is approximately 440 nm. An @El wavelength nearly aligned with a second peak absorption at wavelength it can be made to spread. When this is done, the controller will set the first drive emission. At least one @El to selectively emit (128a) and/or second drive emission (128b) sourceII (130) will selectively activate the first arcElg and/or the second arc-Elg it can be played in this way. In this way, the system is located in the first photoluminescent clginEl(126a) of the controller. and/or selectively illuminate the second photoluminescent keinEl 126b how it can work.

Although the propulsion emissions can be attributed to Ela (128) specific energy wavelengths. Although there are no propulsion emissionsII, each of the first photoluminescent k-i (126a) or one or more photoluminescent klgmlil placed in the second photoluminescent k-i (126b) it can be configured to activate it selectively. Drive emissionsIZ(128) usually blue 500nm). In some applications, the JEJ against one or more of the propulsion emissions (128) wavelengths, wavelengths in the color range of approximately one beyond violet can occur ( ~390-450 nm) In some cases, the propulsion emissions II (128) are each from approximately 500 nm may be less, such that the propulsion emissions (alZS) are almost invisible. until @El resourcesII yayEEr. Although the name LED bows is given, each bow eg halogen lightingCluorescent lightingHand-emitting diodes (LEDs), organic LEDs (OLEDs) polymer LEDs (PLEDs) additive lighting or excitation emissionsEI (128) from any ISIEI source, such as another form of disclosure. kars[[l]is possible.

In BazEyapllândlElnas, the lighting system (120) is divided into more than one density @El photoluminescent lights (126) can be manipulated to activate each of them. For example, the controller may have a fretted drive emission (128) from at least one LIKI source (130). it can be played to adjust the intensity. The intensity of the drive emission (128) is one or more incoming spring voltage / intelligent duty cycle supplied to the hands and/or can be adjusted by changing a size. In some lglKl, at least one lglKl source130) may consist of at least one LED arc.

The LED spring can be operated by varying the intensity. An example When built, the controller provides a first signal within a normal operating range for an LED arcEEE. LED @Hand source can work in such a way that it can be used in intensity. In addition, the controller have a higher density than the first density, capable of exceeding the normal range of Çalghia It can operate in a way that drives the relevant source at a second density that can be. description here as it is, an LED arcElîElçin is more low operating latitudes- and may correspond to a full duty cycle (eg, about 45 C).

Threshold lacquer[glEtlan at lower lacquer, controller at first density or second density Ellîlkaynagllgallgtlüb.

At least one EEKaynagEIüBO) enterprise may be in communication with the lebklablelçlcontroller. any lacquer hand measuring device or a thermometer tool an environment can be identified by lelakHg. If the controller operating sElaklIglII threshold lelsikHgilEi If it detects that it has passed, the controller can supply LSllZl source only at first intensity and second It can be played in intensity. Second intensity of an excitation emission, photoluminescent kîtnlZI(126) can be applied to excite, thus photoluminescent k-idan (126) A spring-loaded scratch emission is positioned in front of the vehicle (124) in an occupant configuration. a surface can contain at least one class. Although the lighting system (120) is Although the 124 is shown as a hood, the lighting system can be used as a hood, e.g. The trunk lid can be used as a luggage compartment.

In the bazurapilândlîilnas, each of the photoluminescent k-illars discussed here (eg. A handheld system made to convert 126) propulsion emission (128) to tripleZISl emission (136) may consist of organic or inorganic fluorescent dye. For example, photoluminescent k-ilar (126) with ethylene, xanthene, prophyrin, phthalocyanine or first absorption range and emission luminance A special Stroke shift described - a photoluminescent made of other suitable material may occur. In BazEyapllândIelnas, photoluminescent k-ilar (126) is from the phosphorus group. may consist of at least one selected inorganic luminescent material. inorganic luminescent material, Like YAG:Ce, it can be selected from Ce-katkEIJJgarnet group. In this way, photoluminescent light (126) a trio of cells, each of which will excite a specific photoluminescent material and have the desired color. Constructed to emit emission from EllBilgluyarli emission (128) aI-n wavelengthsII can be selectively activated by a wide range.

Now refer to Figure 8, as a three-markable or retractable mark. The lighting system 120 is shown, including a canopy 142 that can be applied.

The canopy can be attached to the inner surface (127) of the cover (122) or some other When it sticks, it can be pulled back into a housing (143). Housing, inner surface (127) can be connected or integrated as a cover 122. Canopy (142) different] materials, eg polymeric, metallic etc. may be material. In bazlîyapllândlîilnas, The canopy (142) can be flexible and has retractable spring assemblies (144) sides and one or more redundant connector(146) in an extended position (as shown) can be held. On the baseEquipments, the canopy 142 is made of nearly rigid material or an almost flexible, which can be fixed to the vehicle 124 by joining the elements. material and can be arranged close to the engine compartment (132). canopy engine In any of the arrangements for the EllBiasD position of the pane, the canopy (142) can be arranged in such a way that the photoluminescent k-leds (126) come from at least one tri-EISI emission (136) rests on a masking surface (148) of the canopy (142) Shade (142) from masking surface (148) to form a cut-out k- (152) It may consist of one or more graphics (150) and/or characters that are truncated or combined. Each masking graphics (150) or characters, no matter how much is specified as a truncated km It may correspond to a sheath with increased or decreased conductivity relative to its surface (148). Here In each of the exemplary structures of the canopy (142) that is dealt with, one or more graph (150) to a contrast level of the masking surface (148) @El conductivity relative to the graph. Do it in a way that you can have. In this way, photoluminescent k-leds (126) are at least three[ElSl emission from one ( illuminated so that the graphics (150) can be seen and the enlightened Iatuîz'jßlo.

One or more graphics (150) and/or character backlightingIEI It may correspond to a message (154) that will be illuminated in the configuration. Message is a symbol in the form of, for example, a danger symbol, a word, and/or a different symbol.

As shown in Figure 8, the message forms the word “help”, which is used in an emergency. An emergency message is displayed, which can be displayed to alert others. BaseHand In YapiEndlElnas, the canopy can be changed so that more than one can be placed on the canopy (142). one of the symbol or message can be illuminated. In this way, the lighting system (120) is set to the vehicle (124) hood or any cover (EQ122) is in the unlocked position. provides the opportunity See fig. 9-[glia, lighting with an adjustable relevant transmission device(160)] system 120 is shown. The assembly 160 is mounted on an adjustable support 166. an embedded reflector 162 or a tunable photoluminescent light 64 may be formed.

In the different models discussed here, the adjustable support (166) is located in the engine compartment. (132) a hilal link to one or more supports placed approx. can be done in the configuration. On this build, @Bailetim Sahnelîd160) tool (124) It can be edited to provide @El to different nearby locations. For example, in Figure 9 As shown, the assembly 160 is arranged such that the tool 124 is a wheel. The slot is correctly oriented with an adjustable setting (168).

In BazEyapUândlîn'nas, the reflector (162) consists of at least one of the photoluminescent lights (126) It can be used to reflect some of the spring dew emission 136. This In constructions, çEISI emission (136) converted from propulsion emission (128) In alIIEl BazElyapllândEnas, at least one @El with tunable photoluminescent k-i (164) The source 130 can be used to receive drive emission. Drive emission (128) In response to receiving the tunable photoluminescent k-i (164) drive emission (128) can convert to adjustable frequency emission (168) and these keep the vehicle in mind (124) it can be mistaken to illuminate many features that have been built in. Adjustable @Hand transmission Vehicle (124) using different types of equipment (160) It can illuminate the different regions located nearby. These regions, the middle (124) may be close to the hood and/or body of the vehicle and to simplify the view of the vehicle (124) and It can provide useful task to improve security.

Now look at Figure 10[g]iEtia, at least one MIDWIFE! Constructed to control the illumination of the source (130), the ElBrE controller (172) A block diagram of a luminescent system 120 is shown. Controller (172) agent& may be in communication with a communication bus (174). Communication main way (174) differentirac The states can be configured to transmit the communicated signals to the controller (172). For example, communication bus (174), controller (172), an intermediate drive selection, an ignition condition, a distress or indicator signal, source of lglKl (16) a remote activation or illumination any other system that can be used to control or adjust the lighting of the system (120). It can be configured to communicate with any information or control signal.

Controller (172) will set a proportional density of each of the operating conditions and/or It can be configured to receive at least one signal that defines its amplitude. These signals are, for example, different vehicle systems, such as a tachometer, a lilac[E gauge, a HInc, to the EEEa controller (172) can be connected. In this construction, the controller (172) E of the lighting system (120) sourcegll ( selectively illuminating an operating state (e.g. engine running rate, engine speed, vehicle speed, a turn indicator status etc.) to provide information to an operator of the corresponding agent (124). it can be done. When this is done, the controller (and the second springEIEI (176b) will activate by scattering and almost in turn the first photoluminescent element EEGlZöa) and the second photoluminescent element EEGIZöb).

The controller 172 will receive signals from the communication bus 174 and the first drive emission (138a), second emission (138b) and EE with different combinations of these sourcegllîd130) may consist of a processor (178) with multiple circuits. Processor (178) with EE source (130) A memory built to store instructions to control its activation It can be in contact with (180). Controller (182) with separate & ambient EE sensor (182) may be in contact. The ambient EE sensor (182) can detect an EE state, for example medial (124) The approximate surrounding environment can be operated to convey a biased brightness or intensity level. In response to the Environment Eg, the controller (172) EE sourcesEE (130) each have a to adjust the density of an EE that emits 1 or more (176a, 176b) EEÇilZEEll density, a duty cycle, EE from buildable heat sources (130) The source 130 can be adjusted by controlling the voltage or voltage supplied.

On some devices, the controller 172 is a vehicle control module and/or a user. The communication main path (174) with the interface may be in communication with the vehicle. UseEra face, a It can correspond to the human machine interface (HMI) (184). vehicle control module or In response to an input from its face, the controller 172 rings an inner surface of the cover 122. At least one photoluminescent kEnlIa126 placed on (127) is selectively illuminated Whatever Although the controller (172) is powered by reference to the lighting system (120), the controller The illumination system (172) can be used in a similar way as (12).

In order to understand the current angle more separately, the following point It is noted that the terms "almost" and "approximately" refer to any Quantitative comparison, value, measurement or other aspect “Almost” and “approximately” are used to represent the degree of uncertainty. The terms "as" are also used herein as a quantitative aspect, the essential element of the article in question. how much does it differ from the specified reference[l]]Zl The point is that the concepts of the present invention are separated from the above- Changes and modifications can be made to the specified structure and also the point is intelligible that these concepts are otherwise starkly in terms of the language of the claims. unless specified, it is within the scope of the following claims.

Claims (20)

REQUESTS 1. A photoluminescent bird placed on an inner surface of a cover of a chamber, an @El-welded photoluminescent lamp placed on an End-l cover made to emit emission, converting the first wavelength to at least a second wavelength longer than the first wavelength Yapilând-[gill an illumination system for a vehicle. 2. The lighting system according to claim 1, wherein the hood comprises a hood configured to enclose an engine compartment and at least one of a corresponding trunk lid structured to enclose a luggage compartment. 3. The lighting system according to claim 1, wherein an engine compartment is located in a forward position. 4. Illumination system according to claim 1, comprising an appropriate controller configured to illuminate the light source effectively. 5. The lighting system according to system 4, where the controller is configured to use the SUB source to emit at a first density or a second density Ella. 6. Illumination system according to claim 5, where the controller is constructed to provide an incremental information in a reduced duty cycle to produce a second density relative to the first density. 7. Illumination system according to claim 5, where the second density is constructed to radiate the hand with a plusEllIhlSl luminosity. 8. The lighting system according to claim 5, wherein the controller is configured to receive a health signal. 9. In response to the controller's response to a leachate exceeding a leachate threshold, the second density was built-[according to system 5, the light leaching system. 10. At least one photoluminescent k-i placed on an inner surface of a cover, placed near the OUTside of the chamber and constructed to emit light at the first wavelength, with a small source of IE, whose photoluminescent light will return from the first wavelength at least to the first wavelength, How to make a lighting for a tool compartment 11. The lighting according to claim 10, where the disk is the partition corresponds to an access zone. 12. Illumination system according to claim 10, wherein a photoluminescent clad hood insulator includes a coating placed on the Eilizer of at least one kg. 13. Illumination system according to claim 1, wherein at least one photoluminescent light comprises a first photoluminescent light and a second photoluminescent light. 14. At least one @El source is constructed to excite the first photoluminescent lamp, constructed to induce a first photoluminescent lamp and a second photoluminescent lamp. 15. Illumination system according to claim 14, where a first excitation emission is constructed to emit a first photoluminescent light substantially related to a second excitation emission made to illuminate the second photoluminescent light. 16. At least one photoluminescent k-i, with a cover placed on an inner surface of the chamber, disposed near the outer shell of the chamber and constructed to emit radiation at the first wavelength. A vehicle made to convert to at least a second wavelength. a lighting system for a compartment. 17. Illumination system according to claim 16, wherein the closure is constructed to selectively close the chamber. 18. The illumination system according to claim 16, comprising a canopy constructed from the inner surface of the cover so that the access zone of the compartment extends to an approximate surface. Illumination according to claim 16, where the canopy corresponds to an operable mask to pass a freckle emission from photoluminescent k-through a cut-off k- 20. The lighting system according to claim 19, wherein the truncated frame comprises at least one of a character and a graphic that is selectively illuminated by the emission of strawberries.