This patent document relates to lighting systems, devices, and techniques, including designs and operations of lighting devices and systems based on semiconductor light-emitting diodes or laser diodes.
A light-emitting diode (LED) is a semiconductor light source. An LED includes semiconducting materials doped with impurities to create a p-n junction, in which electrical current can easily flow one directionally from the p-side (anode) to the n-side (cathode), but not in the reverse direction. Charge-carriers (e.g., electrons and holes) flow into the p-n junction from connecting electrodes at each end of the junction having different voltages. For example, when an electron combines with a hole, the electron falls into a lower energy level and can release energy in the form of a photon, e.g., emitting light. This effect is referred to as electroluminescence. The wavelength of the light emitted, and thus the color of the emitted light, depends on the band gap energy of the materials forming the p-n junction. For example, bright blue LEDs are based on the wide band gap semiconductors including GaN (gallium nitride) and InGaN (indium gallium nitride). For producing white light using LEDs, one technique is to use individual LEDs that emit three primary colors (red, green, and blue) and then mix all the colors to form white light. Another technique is to use a phosphor material to convert monochromatic light from a blue or ultraviolet LED to broad-spectrum white light, e.g., in a similar manner to fluorescent light bulbs.
Semiconductor LEDs and semiconductor laser diodes (LDs) are known for their energy efficiency in converting electricity into light and can be used to construct energy-efficient lighting sources or devices for a wide range of applications. For example, LEDs have been adopted in various lighting devices to replace or substitute fluorescent and candescent lights. LED lighting devices can be designed based on DC power supplies such as batteries or AC power supply.
Lighting techniques, devices and systems are provided to construct solid-state lighting devices and systems to provide energy-efficient illumination including personal lighting devices, desktop lighting devices, and ceiling/overhead lighting devices based on semiconductor-based solid-state light sources such as LEDs or laser diodes.
In one aspect, a lighting device based on semiconductor light-emitting diodes (LEDs) includes an illumination plate including an LED module having LEDs that emit visible light, an optical plate module including a transparent slab having top and bottom surfaces and a light input side facet between the top and bottom surfaces engaged to the LED module to receive visible light from the LED module, and an optical layer formed on the top surface of the transparent slab to be optically transparent or optically reflective to light inside the transparent slab; a support plate having a top plate end and a bottom support end, the top support end being engaged to the illumination plate to allow the support plate and the illumination plate to pivot at different positions relative to each other; and a base plate engaged to the bottom support end of the support plate to allow the support plate and the base plate to pivot at different positions relative to each other, in which the illumination plate, the support plate and base plate collectively form a reconfigurable lighting structure that enables a configuration where the base plate operates as a base to allow the support plate to position the illumination plate over the base plate as a desktop lighting device.
Implementations of the lighting device can optionally include one or more of the following features. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate can be engaged to enable the support plate and the base plate to be folded against each other. For example, the base plate can include a power supply that provides electricity to energize the LED module for emitting the visible light, and the support plate can include an electrically conductive connection to electrically connect the LED module and the power supply to allow the electricity to be transferred to the LED module. For example, the optical layer can be a controllable optical layer that is responsive to a control signal to be optically transparent or optically reflective to light inside the transparent slab, and the base plate can include a control circuit that generates the control signal to the illumination plate for controlling the controllable optical reflector layer. For example, the controllable optical reflector layer can be configured to be (1) optically transparent when the power to the LED module is off and (2) optically reflective when the power to the LED module is on. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate can be engaged to enable the support plate and the base plate to be folded against each other, and the controllable optical reflector layer can be controlled to be optically transparent when the illumination plate, the support plate and the base plate are folded together. For example, the support plate can be made of a transparent or translucent material and can include a transparent electrically conductive material to provide the electrically conductive connection. For example, the power supply in the base plate can be structured to include one or more batteries. For example, the illumination plate can include an optically reflective layer around side edge of the transparent slab to reflect light incident to the edge back to the transparent slab to increase light output at the top or bottom surface. For example, the illumination plate can include a metal part in contact with the LED module to dissipate heat out of the LED module.
In another aspect, a lighting device based on semiconductor LEDs includes an LED module having LEDs that emit visible light, a transparent slab having top and bottom surfaces and an input side facet and additional side facets between the top and bottom surfaces, the transparent slab being coupled to the LED module via the input side facet to receive visible light from the LED module, one or more side facet films formed on the additional side facets of the transparent slab to reflect light exiting the transparent slab via the additional side facets back to the transparent slab so as to enable the transparent slab to direct the received light out of the transparent slab via the top and bottom surfaces, an optical layer formed on the top surface of the transparent slab to be between (1) a first optical state that is optically transparent or translucent to light in the transparent slab and (2) a second optical state that is optically reflective to light in the transparent slab, and a lighting control mechanism that is coupled to control output of light from the transparent slab based on the first and second optical states of the optical layer with respect to the light inside the transparent slab to either output light via both top and bottom surfaces when the optical layer is in the first optical state to the light or to output light via only the bottom surface when the optical layer is in the second optical state to the light.
Implementations of the lighting device can optionally include one or more of the following features. For example, the optical layer can include a stack of dielectric films configured to transmit light in a first optical polarization and to reflect light in a second polarization that is orthogonal to the first optical polarization, and the lighting control mechanism can be configured to control an optical polarization of light inside the transparent slab to be in either the first optical polarization or in the second polarization. For example, the optical layer can be configured as a controllable optical layer that changes between the first and second optical states in response to a control signal applied to the controllable optical reflector layer, and the lighting control mechanism can be coupled to the optical layer to supply the control signal. For example, the controllable optical layer can include a liquid crystal layer that responds to an applied voltage as the control signal to change between the first and second optical states. In some implementations, for example, the controllable optical layer can be configured as a controllable optical diffuser structured to include a top transparent electrode, a light diffusing layer that is below the top transparent electrode that responds to an applied voltage as the control signal to change an amount of diffusion of light based on the applied voltage, and a bottom transparent electrode formed below the light diffusing layer which is located between the bottom and top transparent electrodes. In some implementations, for example, the controllable optical layer can be configured as a controllable optical reflector structured to include a top polarization selective reflector configured to transmit light in a first optical polarization and to reflect light in a second polarization that is orthogonal to the first optical polarization, a liquid crystal layer that is formed below the top polarization selective reflector that responds to an applied voltage as the control signal to change optical polarization between the first and second optical polarizations, and a bottom polarization selective reflector formed on top of the top surface of the transparent slab and configured to transmit light in the first optical polarization and to reflect light in the second polarization that is orthogonal to the first optical polarization. For example, each polarization selective reflector can be configured to include a stack of dielectric films. In some implementations, for example, the lighting device can include a battery power supply to supply electricity to the LED module for emitting the visible light. In some implementations, for example, the lighting device can include a mounting unit for mounting the lighting device to a wall or other surface. In some examples, the LED module and the transparent plate can be engaged to form an illumination plate with LED module being on a first end of the illumination plate; and the lighting device can be structured to further include a support plate having a top plate end and a bottom support end, the top support end being engaged to the illumination plate to allow the support plate and the illumination plate to pivot at different positions relative to each other, and a base plate engaged to the bottom support end of the support plate to allow the support plate and the base plate to pivot at different positions relative to each other, in which the illumination plate, the support plate and base plate collectively form a reconfigurable lighting structure that enables a configuration where the base plate operates as a base to allow the support plate to position the illumination plate over the base plate as a desktop lighting device. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate are engaged to enable the support plate and the base plate to be folded against each other. In some implementations, for example, the base plate can include a power supply that provides electricity to energize the LED module for emitting the visible light, and the support plate can include an electrically conductive connection to electrically connect the LED module and the power supply to allow the electricity to be transferred to the LED module. In some implementations, for example, the optical layer can be configured as a controllable optical layer that is responsive to a control signal to be optically transparent or optically reflective to light inside the transparent slab, the lighting control mechanism can be coupled to the optical layer to supply the control signal, and the base plate can include a control circuit that generates the control signal to the illumination plate for controlling the controllable optical reflector layer.
Various features are described in detail in the drawings, the description, and the claims.
The described examples of lighting techniques, systems, and devices based on semiconductor-based solid-state light sources such as LEDs or laser diodes use an illumination plate to receive the generated light from one or more LEDs or laser diodes and to process the received light to exhibit desired spatial distribution of light power across the illumination plate and desired direction of the output light from the illumination plate. This illumination plate operates as the “lighting engine” of the exemplary personal lighting devices and systems described in this patent document.
In one aspect, a lighting device based on semiconductor light-emitting diodes (LEDs) includes an illumination plate, a support plate having a top plate end and a bottom support end, the top support end being engaged to the illumination plate to allow the support plate and the illumination plate to pivot at different positions relative to each other, and a base plate engaged to the bottom support end of the support plate to allow the support plate and the base plate to pivot at different positions relative to each other, in which the illumination plate, the support plate and base plate collectively form a reconfigurable lighting structure that enables a configuration where the base plate operates as a base to allow the support plate to position the illumination plate over the base plate as a desktop lighting device.
In some implementations, for example, this illumination plate can be constructed to include an LED module having LEDs that emit visible light, an optical plate module including a transparent slab having top and bottom surfaces and a light input side facet between the top and bottom surfaces engaged to the LED module to receive visible light from the LED module, and an optical layer formed on the top surface of the transparent slab to be optically transparent or optically reflective to light inside the transparent slab. The optically transparent or optically reflective property of the optical layer formed on the top surface can be controlled by either controlling the polarization of light incident to the top optical layer or to control the top optical layer itself so the top optical layer can be either optically transparent or optically reflective while directing light in the illumination plate to exit as output light at the bottom surface of the illumination of the plate. This property of the two optical states of the top optical layer of the illumination plate can be implemented in various configurations as described further in this document.
Implementations of the lighting device can optionally include one or more of the following features. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate can be engaged to enable the support plate and the base plate to be folded against each other. For example, the base plate can include a power supply that provides electricity to energize the LED module for emitting the visible light, and the support plate can include an electrically conductive connection to electrically connect the LED module and the power supply to allow the electricity to be transferred to the LED module. For example, the optical layer can be a controllable optical layer that is responsive to a control signal to be optically transparent or optically reflective to light inside the transparent slab, and the base plate can include a control circuit that generates the control signal to the illumination plate for controlling the controllable optical reflector layer. For example, the controllable optical reflector layer can be configured to be (1) optically transparent when the power to the LED module is off and (2) optically reflective when the power to the LED module is on. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate can be engaged to enable the support plate and the base plate to be folded against each other, and the controllable optical reflector layer can be controlled to be optically transparent when the illumination plate, the support plate and the base plate are folded together. For example, the support plate can be made of a transparent or translucent material and can include a transparent electrically conductive material to provide the electrically conductive connection. For example, the power supply in the base plate can be structured to include one or more batteries. For example, the illumination plate can include an optically reflective layer around side edge of the transparent slab to reflect light incident to the edge back to the transparent slab to increase light output at the top or bottom surface. For example, the illumination plate can include a metal part in contact with the LED module to dissipate heat out of the LED module.
The support plate 120 includes top plate end being engaged to the illumination plate 110 to allow the support plate 120 and the illumination plate 110 to pivot at different positions relative to each other, and a bottom support end engaged to the base plate 130 to allow the support plate 120 and the base plate 130 to pivot at different positions relative to each other. This reconfigurable folding lighting structure allows a user to adjust the position of the illumination plate 110 with respect to its lateral or horizontal position with respect to the base plate 130 and the height or vertical position of the illumination plate 110 with respect to the base plate 130.
One of operating options in the folded configuration is to make the top optical layer of the illumination plate 110 to be transparent so the LED light can exit from the top optical layer as a lighting device to be placed on a floor, a wall, a ceiling or other surface. This expands versatile use of the lighting device 100.
The control functions of the reconfigurable lighting device 100 can be implemented in various ways. For example, in one implementation, the base plate 130 can be designed to include a power supply that provides electricity to energize the LED module in the illumination plate 110 for emitting the visible light and the support plate 120 includes an electrically conductive connection to electrically connect the LED module in the illumination plate 110 and the power supply in the base plate 130 to allow the electricity to be transferred to the LED module. When the top optical layer in the illumination plate 110 is a controllable optical layer that is responsive to a control signal to be optically transparent or optically reflective to light inside the transparent slab, the base plate 110 can include a control circuit that generates the control signal to the illumination plate 110 for controlling the controllable optical reflector layer. In other implementations, the control functions may be implemented in the top of the illumination plate 110 or the side of the support plate 120.
The middle support plate 120 may also be made of a transparent material so that the top illumination plate 110 can appear to be suspended in the air to make the device 100 more appealing to certain consumers. When electrically conductive paths need to run through the support plate 120, e.g., when the power supply and control are placed in the base plate 130, conductive transparent material can be used to form the conductive paths.
The illumination plate 110 in
In
The example in
The top optical layer on the top surface of the illumination plate 110 can be implemented in various ways and some examples are provided in
Referring to
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The illumination plates as described above, including the example in
In another aspect, a lighting device based on semiconductor LEDs is disclosed. The lighting device includes an LED module having LEDs that emit visible light. The lighting device includes a transparent slab having top and bottom surfaces and an input side facet and additional side facets between the top and bottom surfaces, in which the transparent slab is coupled to the LED module via the input side facet to receive visible light from the LED module. The lighting device includes one or more side facet films formed on the additional side facets of the transparent slab to reflect light exiting the transparent slab via the additional side facets back to the transparent slab so as to enable the transparent slab to direct the received light out of the transparent slab via the top and bottom surfaces. The lighting device includes an optical layer formed on the top surface of the transparent slab to be between (1) a first optical state that is optically transparent or translucent to light in the transparent slab and (2) a second optical state that is optically reflective to light in the transparent slab. The lighting device includes a lighting control mechanism that is coupled to control output of light from the transparent slab based on the first and second optical states of the optical layer with respect to the light inside the transparent slab to either output light via both top and bottom surfaces when the optical layer is in the first optical state to the light or to output light via only the bottom surface when the optical layer is in the second optical state to the light.
Implementations of the lighting device can optionally include one or more of the following features. For example, the optical layer can include a stack of dielectric films configured to transmit light in a first optical polarization and to reflect light in a second polarization that is orthogonal to the first optical polarization, and the lighting control mechanism can be configured to control an optical polarization of light inside the transparent slab to be in either the first optical polarization or in the second polarization. For example, the optical layer can be configured as a controllable optical layer that changes between the first and second optical states in response to a control signal applied to the controllable optical reflector layer, and the lighting control mechanism can be coupled to the optical layer to supply the control signal. For example, the controllable optical layer can include a liquid crystal layer that responds to an applied voltage as the control signal to change between the first and second optical states. In some implementations, for example, the controllable optical layer can be configured as a controllable optical diffuser structured to include a top transparent electrode, a light diffusing layer that is below the top transparent electrode that responds to an applied voltage as the control signal to change an amount of diffusion of light based on the applied voltage, and a bottom transparent electrode formed below the light diffusing layer which is located between the bottom and top transparent electrodes. In some implementations, for example, the controllable optical layer can be configured as a controllable optical reflector structured to include a top polarization selective reflector configured to transmit light in a first optical polarization and to reflect light in a second polarization that is orthogonal to the first optical polarization, a liquid crystal layer that is formed below the top polarization selective reflector that responds to an applied voltage as the control signal to change optical polarization between the first and second optical polarizations, and a bottom polarization selective reflector formed on top of the top surface of the transparent slab and configured to transmit light in the first optical polarization and to reflect light in the second polarization that is orthogonal to the first optical polarization. For example, each polarization selective reflector can be configured to include a stack of dielectric films. In some implementations, for example, the lighting device can include a battery power supply to supply electricity to the LED module for emitting the visible light. In some implementations, for example, the lighting device can include a mounting unit for mounting the lighting device to a wall or other surface. In some examples, the LED module and the transparent plate can be engaged to form an illumination plate with LED module being on a first end of the illumination plate; and the lighting device can be structured to further include a support plate having a top plate end and a bottom support end, the top support end being engaged to the illumination plate to allow the support plate and the illumination plate to pivot at different positions relative to each other, and a base plate engaged to the bottom support end of the support plate to allow the support plate and the base plate to pivot at different positions relative to each other, in which the illumination plate, the support plate and base plate collectively form a reconfigurable lighting structure that enables a configuration where the base plate operates as a base to allow the support plate to position the illumination plate over the base plate as a desktop lighting device. For example, the support plate and the illumination plate can be engaged to enable the support plate and the illumination plate to be folded against each other, and the support plate and the base plate are engaged to enable the support plate and the base plate to be folded against each other. In some implementations, for example, the base plate can include a power supply that provides electricity to energize the LED module for emitting the visible light, and the support plate can include an electrically conductive connection to electrically connect the LED module and the power supply to allow the electricity to be transferred to the LED module. In some implementations, for example, the optical layer can be configured as a controllable optical layer that is responsive to a control signal to be optically transparent or optically reflective to light inside the transparent slab, the lighting control mechanism can be coupled to the optical layer to supply the control signal, and the base plate can include a control circuit that generates the control signal to the illumination plate for controlling the controllable optical reflector layer.
While this patent document contains many specifics, these should not be construed as limitations on the scope of any invention or of what may be claimed, but rather as descriptions of features that may be specific to particular embodiments of particular inventions. Certain features that are described in this patent document in the context of separate embodiments can also be implemented in combination in a single embodiment. Conversely, various features that are described in the context of a single embodiment can also be implemented in multiple embodiments separately or in any suitable subcombination. Moreover, although features may be described above as acting in certain combinations and even initially claimed as such, one or more features from a claimed combination can in some cases be excised from the combination, and the claimed combination may be directed to a subcombination or variation of a subcombination.
Similarly, while operations are depicted in the drawings in a particular order, this should not be understood as requiring that such operations be performed in the particular order shown or in sequential order, or that all illustrated operations be performed, to achieve desirable results. Moreover, the separation of various system components in the embodiments described above should not be understood as requiring such separation in all embodiments.
Only a few embodiments are described. Other embodiments and their variations and enhancements can be made based on what is described and illustrated.
This patent document claims the priority and benefit of U.S. Provisional Application No. 61/694,737, entitled “LED-BASED PERSONAL AND OTHER LIGHTING DEVICES AND SYSTEMS,” filed on Aug. 29, 2012. The entire content of the before-mentioned patent application is incorporated by reference as part of the disclosure of this application.
Filing Document | Filing Date | Country | Kind |
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PCT/US13/57421 | 8/29/2013 | WO | 00 |
Number | Date | Country | |
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61694737 | Aug 2012 | US |