The present invention relates generally to vehicle ornaments, and more particularly, to an electroluminescent vehicle ornament.
Creating a strong brand identity in the vehicle industry involves creativity and attention to detail. Vehicles such as automobiles, trucks, and motorcycles are often recognized by a badge, insignia, ornament, and/or other cosmetic artifacts. An attention-getting ornament can help promote brand-awareness for a vehicle.
Vehicle ornaments are often installed during manufacture in the factory. Additionally, vehicle ornaments can be installed post-manufacture, in an automobile dealership, third-party shop, and/or by end-users. Vehicle customization is a multi-million-dollar industry. Vehicle customization can include modification of vehicles to boost their performance. Additionally, vehicle modification can also include changes to the vehicle's overall appearance. These aesthetic modifications can include customized vehicle ornaments. Automobile enthusiasts often like to modify and accessorize their vehicles in order to give them a unique appearance.
In one embodiment, there is provided a method of making an electroluminescent vehicle ornament, comprising: fabricating an electroluminescence device; affixing the electroluminescence device within a translucent housing; applying a chromatic tint to at least a portion of the housing; and attaching a connector plug to the electroluminescence device, such that the connector plug is accessible outside of the housing.
In another embodiment, there is provided a method of making an electroluminescent vehicle ornament, comprising: fabricating an electroluminescence device; affixing the electroluminescence device within a translucent housing; applying a chromatic tint to at least a portion of the housing; and affixing a battery to the housing; and
In yet another embodiment, there is provided a method of making an electroluminescent vehicle ornament, comprising: fabricating an electroluminescence device; affixing the electroluminescence device within a translucent housing; applying a chromatic tint to at least a portion of the housing; affixing an alternating current (AC) inverter within the housing; coupling the AC inverter to the electroluminescence device; affixing a controller within the housing; and coupling the controller to the electroluminescence device.
The structure, operation, and advantages of the present invention will become further apparent upon consideration of the following description taken in conjunction with the accompanying figures (FIGs.). The figures are intended to be illustrative, not limiting.
Certain elements in some of the figures may be omitted, or illustrated not-to-scale, for illustrative clarity. The cross-sectional views may be in the form of “slices”, or “near-sighted” cross-sectional views, omitting certain background lines which would otherwise be visible in a “true” cross-sectional view, for illustrative clarity.
Often, similar elements may be referred to by similar numbers in various figures (FIGs) of the drawing, in which case typically the last two significant digits may be the same, the most significant digit being the number of the drawing figure (FIG). Furthermore, for clarity, some reference numbers may be omitted in certain drawings.
Disclosed embodiments provide electroluminescent vehicle ornaments. The vehicle ornaments are backlit with an electroluminescence device installed within a housing. The housing includes a translucent portion that is aligned with the electroluminescence device, enabling light to pass therethrough. In some embodiments, the translucent portion may comprise translucent chrome, and/or a colored film, to create a specific appearance. Some embodiments may include a factory-installed vehicle ornament that is installed by the vehicle manufacturer at the time of the vehicle assembly. Some embodiments may include aftermarket vehicle ornaments that are installed by third-party repair facilities and/or end-users. Some embodiments may include advanced illumination features such as changes in illumination as a function of vehicle operating parameters. Some embodiments obtain power from the vehicle power supply. Other embodiments may utilize a self-contained power source.
As used herein, “translucent” refers to a material or layer that is not completely opaque, and which allows at least some light to be transmitted therethrough, and includes transparent and translucent materials that can be colored or colorless.
Disclosed embodiments utilize an electroluminescence device. The electroluminescence device can include a flexible electroluminescence cell that is activated by an alternating electrical current. The flexible electroluminescence cell can be fabricated in most any shape, and provide an evenly distributed light source, making it well-suited for vehicle ornaments. Disclosed embodiments may utilize an electroluminescence cell such as that disclosed in U.S. Pat. No. 7,148,623 to Vlaskin, et al, dated Dec. 12, 2006, and U.S. Pat. No. 5,912,533 to Lee, et al., dated Jun. 15, 1999, both of which are incorporated herein by reference in their entirety.
A first electrode 108 is disposed on the transparent conductive-coated substrate 106. The first electrode may be comprised of copper, aluminum, gold, or other suitable conductor. A layer of conductive adhesive 110 is disposed on first electrode 108. The conductive adhesive may comprise an epoxy infused with a conductive metal such as silver, gold, nickel, and/or copper. A first electrode tab connector 112 is disposed on the conductive adhesive layer 110. The tab connector 112 may comprise copper, gold, aluminum, or other suitable conductive material.
An electroluminescent dielectric layer 114 is disposed on the transparent conductive-coated substrate 106. In embodiments, the electroluminescent dielectric layer 114 can comprise mixture of phosphor powder, one or more binders, and one or more additional elements to create a light of a desired color. For example, by adding Sm to ZnS, or by adding Cu, Mn and Cl to ZnS, red is obtained; by adding Tb to ZnS, or by adding Cu and Cl to ZnS, green is obtained. By adding Tm to ZnS or by adding Cu and Cl to ZnS, blue is obtained. By making a layer with a mixture of materials related to the three colors, white light can be obtained. By using color filters on the white phosphor layer, it is possible to obtain various kinds of colored light.
A second electrode 116 is disposed on the electroluminescent dielectric layer 114. The second electrode may be comprised of copper, aluminum, gold, or other suitable conductor. A layer of conductive adhesive 118 is disposed on second electrode 116. The conductive adhesive may comprise an epoxy infused with a conductive metal such as silver, gold, nickel, and/or copper. A second electrode tab connector 120 is disposed on the conductive adhesive layer 118. The tab connector 120 may comprise copper, gold, aluminum, or other suitable conductive material. In embodiments, wires may be soldered to the tab connectors 112 and 120 that lead to a crimped terminal connector, which can be connected to an alternating current (AC) power source, such as an inverter to power the electroluminescence device 100. In some embodiments, an encapsulating dielectric may be deposited over the electroluminescence device 100 to hermetically seal it and provide additional protection from moisture and other environmental factors.
In some embodiments, a pattern 209 may be formed in the translucent portion. The pattern 209 can include a plurality of triangular grooves, indicated generally at 211. The pattern 209 can disperse light to create an optical effect, as well as create a cosmetic effect even when the backlit illumination is not present. In embodiments, the grooves may be formed in a mold, such that when the housing is formed via an injection molding process, the grooves are also formed. In other embodiments, the grooves may be formed after the housing is fabricated, via tooling.
A first wire 233 is connected to tab connector 112. A second wire 235 is connected to tab connector 120. The first wire 233 and second wire 235 are connected to a crimped connector plug 237. The plug 237 can be connected to an AC power source for activating the electroluminescence device 100. The AC power source can include an AC inverter that is connected to the direct current (DC) power supply of a vehicle.
The electroluminescence device 180 is enclosed in housing 202. In embodiments, housing 202 may be comprised of a plastic such as polycarbonate, or the like. The housing 202 includes a translucent portion 204. The translucent portion 204 allows light L, that is generated by the electroluminescent dielectric layer 114 to pass therethrough. In embodiments, the translucent portion 204 may be coated in translucent chrome. During daylight conditions, the translucent chrome may appear similar to non-translucent chrome. In darker conditions such as twilight or night, the backlighting of the electroluminescence device 180 can provide an interesting visual effect in which the translucent portion 204 appears to glow.
In some embodiments, a pattern 209 may be formed in the translucent portion. The pattern 209 can include a plurality of triangular grooves, indicated generally at 211. The pattern 209 can disperse light to create an optical effect, as well as create a cosmetic effect even when the backlit illumination is not present.
A first wire 233 is connected to tab connector 112. A second wire 235 is connected to tab connector 120. The first wire 233 and second wire 235 are connected to a crimped connector plug 237. In embodiments, wires 233 and 235 may be connected to their respective tab connectors 112 and 120 via solder, screw terminals, or other suitable mechanism. The plug 237 can be connected to an AC power source for activating the electroluminescence device 100. The AC power source can include an AC inverter that is connected to the direct current (DC) power supply of a vehicle.
In embodiments, the housing comprises a translucent portion that is aligned with the electroluminescence device. In embodiments, the translucent portion of the housing comprises translucent chrome. Embodiments can include a plurality of triangular grooves formed in the translucent portion. In embodiments the reflecting dielectric layer comprises silicon dioxide. In embodiments the reflecting dielectric layer comprises titanium dioxide.
The embodiment shown in
In some embodiments, the power connection 318 comprises a USB-C port. A weather plug 322 may be inserted into the power connection 318 when not charging the battery 306. In embodiments, the weather plug 322 is comprised of rubber, silicone, or other suitable material. The weather plug 322 serves to prevent excess moisture from entering the power connection 318.
The battery 306 is coupled to an AC inverter 308. A wire 310 extends from the AC inverter 308 to a connector 312. In embodiments, the AC inverter 308 outputs alternating current at a frequency ranging from 380 Hertz to 420 Hertz. The connector 312 is configured to connect to terminal connector 346, which provides AC current to electroluminescence device 316. Electroluminescence device 316 may be similar to electroluminescence device 100 or electroluminescence device 180 previously described.
The mounting plate 304 comprises a set of tabs, indicated as 342, that engage with a corresponding set of tabs on the cover 314. The tabs on the cover are indicated as 344. To install the self-contained electroluminescent vehicle ornament 300 on a vehicle, the mounting plate 304 is affixed to the vehicle via adhesive, screws, or other suitable fastening mechanism. The connector 312 is attached to terminal connector 346, and the cover 314 is pressed onto the mounting plate 304 such that tabs 344 engage with tabs 342, as shown in
Embodiments can include a rechargeable battery; a charging port, coupled to the rechargeable battery; an alternating current (AC) inverter, configured and disposed to receive direct current from the battery, and output alternating current to the electroluminescence device; a housing, the housing configured and disposed to contain the electroluminescence device, and the rechargeable battery, and wherein the housing comprises a translucent portion that is aligned with the electroluminescence device.
Electroluminescent vehicle ornament 400 includes an outer bezel 402 that comprises translucent chrome. Two opaque areas 408 and 410 flank a horizontal translucent chrome section 404. The horizontal translucent chrome section 404 may optionally include opaque indicia 406 such as lettering and/or symbols. In this way, in twilight or nighttime conditions, the indicia 406 is clearly visible to observers when the electroluminescence device is activated.
Embodiments may optionally include a processor 602, that is coupled to a computer memory 604. The computer memory may include a non-transitory computer readable medium, such as static random-access memory (SRAM), flash memory, or the like. The processor may be coupled to an input/output interface 606 that provides a plurality of general purpose I/O (GPIO) pins for interfacing with various peripherals. The peripherals can include, but are not limited to, an on/off switch 622, an ambient light sensor 620, an accelerometer 616, and/or a communication interface 618. The processor 602 can execute instructions stored in memory 604 in order to implement functions of disclosed embodiments. In some embodiments, the processor 602, memory 604, and input/output interface 606 may be implemented in a single integrated circuit, referred to as controller 633.
The on/off switch 622 can be used to conserve energy stored in battery 610, for situations such as when the vehicle is not in use, or during daylight conditions. Embodiments may further include an ambient light sensor 620. In embodiments, the ambient light sensor 620 comprises a photoelectric cell that provides a signal to I/O interface 606 that is proportional to the amount of ambient light. In some embodiments, the processor processes the signal from the ambient light sensor 620 to define three ranges of ambient light: daylight, twilight, and darkness. In embodiments, an opening is formed in the housing of the electroluminescent vehicle ornament, and the light sensor 620 is aligned with the opening, such that it can detect ambient light. In embodiments, the light sensor is coupled to the electroluminescence device via the controller 633.
In embodiments, daylight is defined as a light level of 1000 Lux or greater, twilight is defined as a light level ranging from 20 Lux up to 1000 Lux, and darkness is a light level of less than 20 Lux. Some embodiments may utilize different limits for daylight, twilight, and darkness. Some embodiments may include additional ranges, such as bright daylight, overcast, and the like.
Disclosed embodiments can perform different modes of operation based on the ambient light range. As an example, during a daylight range, the electroluminescence device 614 can be deactivated to conserve power. During a twilight range, the electroluminescence device 614 can be activated to a first brightness level, and during a darkness range, the electroluminescence device 614 can be activated to a second brightness level. In embodiments, the first brightness level is brighter than the second brightness level. In the twilight range, the brightness level may be set to a maximum brightness level. This can serve to create a visible optical effect while there is still a considerable amount of ambient light. When the ambient light level is in the darkness range, embodiments can switch to the second brightness level, which may be a reduced brightness level, in the range of 50 percent to 60 percent of the maximum level. This saves power, while still providing a visible optical effect. With less ambient light, less electroluminescent light from electroluminescence device 614 is needed. The brightness level is a measure of how much light is being emitted from the electroluminescence device.
The accelerometer 616 may be present in some embodiments. In embodiments, the accelerometer 616 provides a signal to I/O interface 606 that is proportional to the amount of acceleration of the vehicle. In some embodiments, the processor processes the signal from the accelerometer 616 to define an acceleration mode, and a static mode. The acceleration mode is active when the accelerometer detects acceleration above a predetermined threshold. The static mode is active when the detected acceleration is at or below the predetermined threshold. In embodiments, the electroluminescence device 614 can be activated to a first brightness level in the acceleration mode, and a second brightness level in the static mode. In some embodiments, the first brightness level is brighter than the second brightness level. This can create an interesting visual effect, such as, for example, a vehicle ornament that gets brighter as the vehicle transitions to moving from being stopped.
The communication interface 618 may be present in some embodiments. The communication interface 618 can include a wireless communication interface. In some embodiments, the communication interface 618 can include a Bluetooth interface. The Bluetooth interface can be configured to communicate with a remote electronic computing device 677. Remote electronic computing device 677 can include a tablet computer, smartphone, smart watch, wearable computer, vehicle infotainment system, and/or other suitable remote electronic computing device. The remote electronic computing device may provide additional user interface functions, such as setting a blink rate, brightness level, color control, and the like. In some embodiments, the electroluminescent vehicle ornament may include multiple regions (e.g., upper and lower), with each region having its own corresponding electroluminescence device that can be controlled individually, giving an improved level of customization for electroluminescent vehicle ornaments of disclosed embodiments. Embodiments can include a communication interface, and in some embodiments, the communication interface receives an activation message, and activates the electroluminescence device in response to the message. The activation message can be received from the remote electronic computing device 677.
In embodiments, the memory contains instructions, that when executed by the processor, cause the processor to: set the electroluminescence device to a first brightness level in response to ambient light falling below a daylight level and wherein the ambient light is also above a twilight level; and set the electroluminescence device to a second brightness level when the ambient light falls below a twilight level. In embodiments, the first brightness level is brighter than the second brightness level. Embodiments can further include an accelerometer coupled to the processor. In embodiments, brightness of the electroluminescence device varies as a function of acceleration of a vehicle to which the electroluminescent vehicle ornament is attached. In embodiments, the brightness increases with increasing acceleration of the vehicle.
Graph 800 includes a vertical axis 804 that represents an electroluminescence device level. Three specific points are indicated on the vertical axis 804: the off level 811 (the electroluminescence device is not outputting light), the low level 813 (the electroluminescence device is outputting a reduced light level that is less than the maximum output), and the high level 815 where the electroluminescence device is outputting the maximum light output.
As can be seen by the graph curve 820, the electroluminescence device operates at a low level when the ambient light is below the twilight threshold 833. The electroluminescence device operates at a high level when the ambient light is above the twilight threshold 833 and below the daylight threshold 835. The electroluminescence device deactivates (off level) when the ambient light is above the daylight threshold 835. Thus, the twilight threshold 833 and daylight threshold 835 create three regions that can correspond to three modes of operation in some embodiments. Region 841 represents a darkness mode (e.g., nighttime). Region 843 represents a twilight mode (e.g., dawn, dusk). Region 845 represents a daytime mode. In embodiments, each mode has a corresponding electroluminescence device output pattern and/or level. The pattern can include blinking, and/or color changing.
The flowchart continues with affixing an AC inverter within the translucent housing at 1060. At 1062, the AC inverter is coupled to the ELD. At 1064, a controller is affixed within the translucent housing. In embodiments, the controller is similar to controller 633 indicated in
In embodiments, one or more of the steps depicted in
As can now be appreciated disclosed embodiments provide an electroluminescent vehicle ornament that provides advanced features and ease of installation. Disclosed embodiments are well-suited for aftermarket use to provide customization for vehicles. Embodiments can also be used in a factory-installed environment during the time of manufacture of a vehicle. Disclosed embodiments can function has hood ornaments, trunk ornaments, vehicle badges mounted on the sides of a vehicle, mounted on wheel hubs, door handles, A-pillar, B-pillar, C-pillar, and/or other suitable locations. Disclosed embodiments can be used on motorcycles, bicycles, snowmobiles, all-terrain vehicles (ATVs), boats, scooters, and/or other vehicles, enabling exciting visual effects that can be used to promote vehicle branding and customization. Disclosed embodiments interface with sensors such as light sensors and/or accelerometers to provide dynamic effects as the mode of operation is changed based on environmental conditions such as ambient light and/or vehicle acceleration. The dynamic effects can include, but are not limited to, changing the intensity of light output from the electroluminescent vehicle ornament, changing a blink pattern, changing a color output, syncing a blink pattern and/or color output change to music, and/or other dynamic effects.
Unless otherwise described herein, components of disclosed embodiments are made from plastic, glass, composite, metal, rubber, silicone, or any other suitable material, now known or hereafter developed.
Although the invention has been shown and described with respect to a certain preferred embodiment or embodiments, certain equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of this specification and the annexed drawings. In particular regard to the various functions performed by the above described components (assemblies, devices, circuits, etc.) the terms (including a reference to a “means”) used to describe such components are intended to correspond, unless otherwise indicated, to any component which performs the specified function of the described component (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiments of the invention. In addition, while a particular feature of the invention may have been disclosed with respect to only one of several embodiments, such feature may be combined with one or more features of the other embodiments as may be desired and advantageous for any given or particular application.