JP7275268B2 - Solar lamp with radial elements - Google Patents

Description

RELATED APPLICATIONS This application is based on U.S. patent application Ser. No. 15/804,877, U.S. provisional patent application Ser. It is related to Provisional Patent Application No. 62/417,632, the entire contents of which are incorporated herein by reference.

This document generally describes a collapsible, solar-powered lamp or light that, in addition to providing illumination, also powers and can be powered by an external device, as well as such lamps. describes various physical forms of

"Roughing it" means many things, from self-sufficiency to the outdoors to freedom. In the modern world, a simple and clumsy life also means a lack of electrical and electronic devices that are part of normal modern life and can be viewed as luxuries or necessities. For example, outdoor lighting may be important at night and can be more easily and simply provided by electric lights rather than flames. Similarly, electronic devices for communication (e.g., via various wireless devices such as AM/FM radios, citizen band radios, as well as cell phones and satellite phones) travel in the open, bush, or outback. Sometimes it is convenient for a person, and at other times it can be important, such as when a traveler is injured and needs immediate help. In such circumstances, it may not be practical to carry enough batteries or other power sources (eg, generators) to power the power needs of the entire trip.

These problems are shared and more acute in areas suddenly plunged into devastated living conditions by natural disasters. For example, in the aftermath of a hurricane, typhoon, or major earthquake, conventional power supplies and distribution grids can be widely disrupted. And the need for power supplies is at a premium (for medical care, search and rescue operations, operating communications and computing facilities, etc.). Power sources such as generators may not be readily available, may not be widespread enough to handle the need for lights and other electrically powered things that can be ubiquitous, and may be too bulky. , bulky and in any case can be difficult to transport.

This document generally describes techniques for providing solar-generated power to multiple points of use in a portable electronic device. The point of use can include light emitting diodes (LEDs) that are part of the device, the device has lights, and is a low voltage device that connects to smart phones, tablets, and other portable consumer electronic devices. It can take the form of a lantern with a power plug. A lantern can be physically expandable into a full lantern form, such as a rectangular box or a cylinder or a sphere, and a flat form, for example when the opposite sides are laid flat in planes parallel to each other. It can also be made foldable. Inflation from the flat configuration to the expanded configuration is natural to draw the device into its expanded configuration (to essentially "open" the box automatically from its flat configuration (after a small initiation input from the user)). can be assisted by an elastic cord inside the device that shortens to Expansion can also be aided by pre-adjusted creases, cuts, or different material thicknesses to aid folding. The device may also comprise multiple solar panels, in the box example, each panel being on a different side of the box when the box is inflated, and each panel being on the other side when the box is flattened. so that each panel can be placed back-to-back with each other when the flattened device is folded in half (a device folded in half has solar panels on its two outer surfaces). Forming a flat device with panels that can be easily exposed to sunlight and the battery can later be used to generate light by means of LEDs or to charge external devices such as smartphones (The battery in the device can be charged in order to

Additionally, the device may provide additional functionality apart from the device's ability to provide light and power. For example, the surface of a container comprising a box or other form may be used independently of a device such as a smartphone to provide a more effective antenna to the smartphone than is possible within the smartphone's relatively small case. One or more antennas may be imprinted that can be connected via a power connector to act as an antenna or that can also be connected via a power connector. The lamp can also be equipped with additional electronic devices that can be plugged into external devices such as smartphones and act as peripherals to supplement the functionality of those external devices. Electronic devices can include Bluetooth®, WIFI, GPS, antennas, and a variety of different sensors to support end-user needs when in remote locations off the grid.

The structure of such devices (e.g., solar panels, printed circuit boards for electronic components, LED lights (e.g., grids), and batteries) can all be flattened in configuration when the device is in a compressed configuration. can be in planes parallel to each other so that the device can be folded flat to the extent practical. Such a configuration allows for minimizing shipping costs, allows for maximizing the number of devices that can be shipped to remote locations, and allows users to carry devices in a minimal amount of space. do. This arrangement also allows the folded lamp to rest on a surface (e.g. on a table or hanging from the back of the user's backpack) and allows all the solar panels to generally face the sun. Alternatively, the solar panels can all be coplanar with each other on one side of the lamp when the lamp is folded.

The arrangement of the electronic components of the lamp may be a layered structure with multiple flat parallel layers (eg with printed circuit boards in the middle layers). For example, LED lights may be mounted directly on a printed circuit board to which a solar panel is also mounted (the solar panel is mounted on one side of a particular circuit board and the LEDs on the opposite side, forming a three-layer structure). ). To make such structures even thinner and lighter, thin or flexible circuit boards can be used to construct three-layer assemblies less than a few millimeters thick. Solar cells can be coated with epoxy, ETFE, PET, or other laminates to protect and secure the cells.

In an alternative embodiment, the solar panels can be placed adjacent to flat batteries of similar size to the solar panels (e.g., with the battery behind or on the side of each particular solar panel) and the PCB can be behind both the solar panel and the battery, eg on the opposite side of the battery to the solar panel. The LEDs may be attached sequentially to the PCB on the side of the PCB opposite where the battery is located. Each such layered assembly can be arranged on panels that form the sides of the inflatable and collapsible housing, such as hollow cubes or panels when the housing is in the inflated configuration, among other possible form factors. Other three-dimensional geometric extrusions can be placed, such as on one or more panels of a structure that is relatively flat and rectangular when the housing is in a compressed configuration. The solar panel is also positioned adjacent to the PCB to further minimize overall thickness (e.g., by laying any two or all of the solar panel PCB and battery on the same plane). can For example, the solar panel can be less than 1 mm thick and can be placed adjacent to a PCB that is also less than 1 mm thick. The battery may be adjacent to both the solar panel and the PCB, or it may be behind the PCB or the solar panel. Adjacent placement of the solar panel, PCB, and battery, such as a tri-fold or multi-fold design, further minimizes the overall thickness of the lamp when inflated.

One or more charging plugs and/or antenna plugs may also be provided on the device for smartphones or similar consumer electronic devices to receive power and/or wireless reception and/or other assistance from the lamp. may be connected or may provide power or other assistance to the lamp. In such an example, a portion of the lamp is sealed (the pouch is subsequently sealed) so that the consumer electronic device is protected if the lamp is exposed to rain or falls into a body of water while charging. a charging plug within it so that a consumer electronic device (e.g., a smart phone) can be slid completely into the pouch, attached to the plug and charged watertightly (when closed). A waterproof pouch or other container can be formed that is placed with the portion. As noted above, the charging plug can include an output plug so that the lamp's battery can charge other devices, such as a smart phone, and the lamp can operate from and/or operate from an external battery. can include input plugs so that the can be charged by an external battery (or each can be both an input plug and an output plug depending on the type of device connected to them). be able to).

In one embodiment, a flat bottom panel and a sidewall connected to the flat bottom panel at a first end of the lamp, the sidewall being capable of expanding and contracting by folding and expanding the sidewall, the lamp a flat top panel connected to the side wall at the second end of the lamp opposite the first end of the lamp; , and an electronic assembly having one or more LEDs mounted on a printed circuit board; for data/power connectors configured to power the lamp from a device external to the lamp, or both, and which can be opened and closed by the user to access the data/power connectors. and a housing that is water-tightly sealed when closed by a user.

In some aspects, the housing includes a removable cap connected to the flat top panel by a plastic hinge. Also, the removable cap can form a circumferential seal around it with a corresponding surface attached to the flat top panel. The lamp has a first part attached to the first part of the lamp and a second part attached to the second part on the side of the lamp opposite where the first part is attached. and wherein the first and second portions of the handle include snap connectors for connecting together. Additionally, the lamp may define a sealed interior volume and be inflatable and deflatable. The lamp may alternatively or additionally include multiple charge indicator lights that illuminate multiple lights indicating the current charge level of the battery in response to user input. The flat bottom panel and flat top panel can be sealed to the sidewalls at their edges. Additionally, the data/power connector can be a USB connector that can be configured to pass only power and not data.

In certain aspects, the perimeters of the flat bottom panel and the flat top panel conform to the shape of the sidewalls and are sealed to the sidewalls at their perimeters. Additionally, the flat top panel can comprise a top sheet and a bottom sheet forming pockets for electronic assemblies, the top sheet having holes therein to provide access to data/power connectors.

In one embodiment, a portable device for generating and providing electricity is disclosed. The device is powered by one or more flat solar panels, one or more batteries configured to be charged by power from the one or more flat solar panels, and one or more batteries. one or more lights configured to receive power from one or more batteries and configured to connect to a combined power/data connection of a portable electronic device; an inflatable and collapsible housing configured to hold the solar panel, battery, and lights and to form a hollow interior volume when inflated and a flat panel when deflated. The inflatable and collapsible housing can be in the form of a rectangular box when inflated and can include side panels having diagonal separations that open as the housing moves from the inflated condition toward the collapsed condition. . The device can also include an elastic cord positioned inside the hollow interior volume and having opposed ends each connected to the housing. The elastic cords are also oriented generally parallel to the separations in the side panels so as to tend to pull the separations open or push the separations closed, folding or expanding the device as part of that action. can be

In other implementations, the solar panel, PCB, and battery combination may be integrated into one side of the foldable cube. The cube shape can have valves or other forms of air openings on one or more sides and solar panel assemblies on one or more sides. Air, water or gas can be used to expand the cubes. The electronic assembly is sealed in plastic so as to be watertight (e.g., in a plastic pouch that fits relatively tightly around the electronic assembly to prevent it from moving about relative to the rest of the lamp). can be stopped. TPU, PVC, silicone or other forms of material can be used to seal together and keep water out.

As an example, an app on a smartphone directed to control of such a solar-powered lamp can be provided, allowing the user to wirelessly turn the lamp on or off and change the color or color temperature of the lamp's LEDs. , or other programmed behavior of the lamp, a GUI can be provided on the smartphone via an app. A single computing device (e.g. a smart phone or tablet computer) can change the color of multiple lamps to a variety of different colors coordinated with each other in time or turn on all the lamps at the same time via one application. Multiple lamps can also be controlled individually or in coordinated combinations, such as turning on/off or turning on from one lamp to another in sequence. The computing device can receive data from each lamp, such as data indicating the state of charge of the battery of each lamp, and display such data to the user of the application.

The electronic assembly is fused to the solar panel facing the outside of the cube to concentrate the sun, adjacent (e.g., behind or laterally) to the solar panel, or to the solar cell to be laminated together. It can consist of a PCB board and a battery stacked underneath or placed adjacent to the PCB and solar panel. The LEDs can be placed on the PCB (typically the side opposite the solar panel) to maximize the light output within the foldable lamp. This electronic assembly can include a plurality of switches or sensors to be controlled by a user either remotely or manually. Some switches can face the outside of the interior volume so that the user can turn the lamp on or off or otherwise (e.g. via Bluetooth from a smartphone or similar device or The circuit can be controlled (via a WiFi wireless data connection).

The electronic assembly can have its own housing or tray to further protect it. The housing or tray has holes for the LEDs (and can have a silver coating on the inside facing side of the lamp to maximize the reflection of light into the lamp), a battery for holding it in place. Areas and may have additional fixtures to hold the circuit in place and support the port or antenna. In addition to the plastic housing, the entire electronic assembly can be encapsulated in a layer of plastic to form one of the surfaces of the cubic volume. In other variations, the housing itself can be transparent and sealed directly into the volume of the collapsible cube. The electronic device can be controlled by the user using a multi-sided PCB or by attaching an external component to a single-sided PCB.

In one variation, a multi-sided PCB has solar cells, switches, indicator LEDs, and ports on one side and LEDs on the opposite side. The battery is stacked underneath the PCB and the LEDs are placed around the battery so that no light shines into the housing. The transparent plastic layer may extend across the surface of the solar panel and be sealed to the body of the lamp at its edges. Because some ports or sensors need to be partially exposed to facilitate electrical connections, plastic caps are connected to the outer layer (so that they can be removed and replaced on the port). ) can be placed on ports or sensors. This plastic cap is designed to fit snugly around the ports so that they are accessible and protected. The plastic cap forms a watertight gasket when closed and allows access to the port when open. A port can be a bi-directional USB port with power input and output modes, or it can be multiple ports or connectors. Magnetic ports can also be used to minimize shape and depth. The ports may be arranged perpendicular to the circuit board, or they may be arranged parallel to the immediate side of the circuit board. A watertight cap is a simple but effective way of waterproofing and protecting the parts that need to be accessed by the user.

In the manufacturing process, the port cap can be sealed to the outer layer of plastic as a first step. An electronic assembly can then be inserted between the outer layer of plastic and the inner layer of plastic. In some variations, more than one inner layer and outer layer can be used to protect the electronic assembly. The port cap must be carefully aligned over the port to ensure proper placement. The port cap can be hollow or solid and can have an opening that fits over the port. The multiple layers of plastic surrounding the electronic assembly are then sealed together around the outer edges to form a watertight seal. Tools used to seal or weld the plastic layers may have holes for the port caps to pass through when the outer edges are sealed. In other variations, the entire top surface, including the port caps, can be molded or formed as a single layer, reducing the need to separately seal the port caps. Additional adhesive may be used to ensure that the layers do not shift or move and that everything is held flat. High frequency welding may be used to fuse the materials together. The cap may be constructed from the same material as the plastic layer, or may be any other material that can be effectively fused together with the layer. If a non-sealable type of material is used for the cap, a very strong adhesive can also be used to effectively waterproof it. Adhesives can also be used to form a watertight seal between layers. The layers of material on the electronic assembly are thin or flexible so that switches and sensors can be operated. In other variations, waterproof buttons are inserted or sealed through the top layer to provide access to the buttons. Caps can also be on other surfaces in foldable form and on ports on adjacent PCBs or can be connected by cords. Such a port implementation can be used with any one of the suitable types of lamps discussed below.

In other variations, magnetic surfaces or coils can be used for wireless transmission of power, which can be sealed to one or more surfaces and sealed with waterproof caps or Ziplock® Eliminate the need. For example, a lamp can receive power when the lamp is placed on the Qi pad, or can act as a Qi pad when another compatible device is placed on top of the lamp. A Qi coil may be provided. Such wireless charging can maximize the efficiency of assembly by reducing the number of elements required to waterproof it, making the components of the electronic device more hermetic and watertight. can make it possible. Alternatively, the port can itself be made waterproof, either by applying a coating or through the design of the lamp, also eliminating the need for a waterproof cap.

Multi-powered solar lamps can be equipped with GPS to allow people to track where they are in case of an emergency. Lamps can have numerous sensor types that provide the user with useful information about things such as solar charge status, weather, distance, sound level, vibration, and movement. And these wireless multi-powered solar lamps can provide information to people through their phones via Bluetooth, WIFI, or other types of connections.

The LEDs can have automatic sensors to turn on or off when it gets dark, or change color when it rains. This information can be useful in an emergency and the lamp can send a signal to warn people or convey a notification. This system of multi-powered solar lamps can also share information with each other and create groups of devices. For example, a group of devices can all be sent the same message to start charging other devices at the same time, or all turned on. This connected system of foldable multi-powered solar devices can be easily equipped because they are packable and lightweight. They can be designed to be equipped by airdropping them with other supplies or projecting them elsewhere in an emergency. Once they reach the location they can inflate or collapse depending on what is needed.

Inflating and collapsing can be particularly useful for maximizing solar state of charge and aiming the lamp to expand or change direction relative to the location of the sun. For example, a solar collapsible multi-powered lamp can be in the shape of a flower with leaves. These leaves are trapped within the bulb, and when there is enough sun for the solar panel to recharge the internal battery, the device can expand to maximize surface area. This inflation and collapse can be fully controlled automatically by sensors or manually. Small gears or joints can be controlled to expand or contract, or wires that expand or contract by electrical signals can be used. Smart materials can also be used in similar ways that can respond or change shape either by electrical signals, temperature changes, or other environmental changes. This automation of inflation and folding gives these devices more room to be remotely self-sufficient. Thousands of people can be easily and quickly deployed to provide charging stations or connect to the grid for replenishment and repair during emergencies when a large area blackout occurs. For islands, there is too much pristine surface area in the ocean, so the use of watertight remote power sources that are floating and can be easily deployed increases the potential for power generation.

In some aspects, the one or more flat solar panels are on adjacent sides of the rectangular box when the housing is expanded and on one side of the flat panel when the housing is contracted and coplanar with each other and at right angles to each other. Includes a pair of solar panels arranged. In another aspect, the housing has a folded state in which the flat panel is folded and the solar panel faces are outside the housing in the folded state such that both solar panels are exposed to ambient light in the folded state. are arranged in opposite directions to each other. Also, the surfaces of the side panels can be pre-scored to guide the folding of the side panels when the device changes from the inflated to the collapsed state.

In yet another aspect, the inflatable and collapsible housing can be in the form of a polygonal star, with the solar panels extending longitudinally away from the center of the star and down the outer edges (points) of the star. and each tip of the star can be folded into a flat panel when the device is folded. A star can have one or more solar panels at its tip, or apex. The solar circuit assembly can be waterproofed inside a housing or box, which can be sealed or attached directly to one or more tips of the star. Stars can be cut from plastic or other material as separate points, pre-folded, and the points connected together to form a complete star. The process of using flat surfaces that can be pre-folded and scored allows for easy folding and inflation. Small holes or lines can be laser cut or imprinted into the material to further facilitate smooth folding and unfolding.

In the star format, a waterproof LED strip can be connected to the solar circuit and aimed through the star, or the LEDs can be placed on the back side of the circuit. Magnets, hook-and-loop fasteners, or small ties can be used to hold the star in its expanded shape. The same type of design can also work for flower shapes or other multi-sided arrangements. The material can be printed with patterns or different transparencies to control the LEDs. Because dangling stars naturally twist in the wind, small sensors or stabilizers, e.g. can be used.

In another aspect, the inflatable and collapsible housing can be in the form of a frusto-conical shape when inflated, the truncated end of the cone being the opposite end of the device from the proximal end of the cone. and can move proximally when the device is collapsed. In such embodiments, the solar panel can be placed on the flat truncated end of the cone, the flat proximal end of the cone, or both. In this variant, the loudspeaker can be placed at the smaller end or the larger end of the cone and oriented to project sound into the cone. Also, in such embodiments, the housing can have a plurality of flat walls as the walls defining the perimeter of the cone. In still other aspects, the cone can house an LED, a battery, and act as a portable light bulb that expands and then collapses. The cone can be plugged into a larger system of flat battery packs and flat solar panels. This flat-pack solar energy system can be easily transported and can provide small-scale residential off-grid power. In yet another aspect, the inflatable and collapsible housing is in the form of a plurality of connected flat rectangular panels configured to be inflated by being rolled into a multi-sided tube and collapsed by being unfolded into a flat sheet. Yes, some of the flat rectangular panels incorporate solar panels.

In yet an additional aspect of the device, the one or more batteries may comprise a pair of batteries each positioned behind a respective one of the solar panels, and the system is configured such that either solar panel and the battery can power one or more lights and one or more connectors. Further, the device can include sealable and non-sealable pockets arranged to protect the electronic device from water outside the housing, and the one or more electrical connectors are arranged inside the pocket. be done. Additionally, the solar panel, battery, and light have one or more transparent surfaces to allow sunlight to reach the solar panel and light from the light to reach the interior of the housing. can be sealed in one or more pockets with The device also communicates via one or more connectors to provide data regarding the operation of the device to an application running on the electronic device to enable that data to be displayed to a user of the device. A controller may also be provided.

In another embodiment, a method of charging a consumer electronic device using a solar powered lamp is disclosed. The method includes one or more flat solar panels, one or more batteries configured to be charged by power from the one or more flat solar panels, and one or more batteries powered by the one or more batteries. placing a solar-powered lamp in the visible light path of the light source and connecting the lamp to the consumer electronic device by electrical cords connected to one or more batteries; and transmitting power from the consumer electronic device to the lamp or from the lamp to the consumer electronic device via the electrical cord.

In certain implementations, the systems and techniques described herein can provide one or more advantages. For example, providing a highly portable device that can function as both a lamp and charger for a variety of consumer electronic devices and that can receive charging and/or data from other devices. can be done. The portable device can be placed in its expanded configuration to provide evenly distributed light in a space such as a campsite or darkroom. Also, it is easy to ship or transport with the solar panel facing outwards when folded or inflated so that it can be charged by ambient light whenever ambient light is available. Can be compressed or folded. The device may also be packaged such that its own electronics are watertight from the outside of the device to provide protection in the difficult environments in which such charging and lighting devices are most likely to operate. , a sealable housing in which a charging smart phone or other portable electronic device can be placed. The charging port of the device may also be located on the outer edge of the device and positioned thereon to keep it watertight when not connected to an external device and for connection to an external device. It may have a small sealable cap that can be removed (at which point the connection may or may not be watertight). In some implementations, multiple devices with solar panels are electrically daisy-chained to provide additional charge to the battery bank so that the charge generated by the user can be tailored to the specific needs of the situation. can be connected. As a result, users of such devices are able to solve multiple problems in a way that is simple and works even in harsh environments.

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features and advantages will be apparent from the description and drawings, and from the claims.

FIG. 1A shows the lighting and charging device in expanded form. FIG. 1B shows the lighting and charging device flattened. FIG. 1C shows the lighting and charging device in flat form. FIG. 1D shows a sealable enclosure on one side of the lighting and charging device. FIG. 1E is an exploded view of the lighting and charging device. FIG. 1F shows a side view of the lighting and charging device in an expanded configuration. FIG. 2A shows the lighting and charging device in a compressed and folded mobile configuration. FIG. 2B shows the lighting and charging device unfolded and folded. FIG. 2C shows the lighting and charging device from behind in the folded configuration. FIG. 2D shows the lighting and charging device in folded and suspended form from both sides. FIG. 2E shows the lighting and charging device in inflated form as a seated and hanging lantern. FIG. 2F shows a lighting and charging device suspended and functioning as a lantern. FIG. 3A shows a two-sided schematic diagram of the electronic structure for the electronic assembly of the lighting and charging device. FIG. 3B shows a two-sided schematic diagram of the electronic structure for the electronic assembly of the lighting and charging device. FIG. 4A shows a lighting device in the form of a collapsible truncated cone. FIG. 4B shows a lighting device in the form of a collapsible truncated cone. FIG. 5A shows the lighting device in roll form. FIG. 5B shows the lighting device in roll form. FIG. 5C shows the lighting device in rolled form. FIG. 5D shows the lighting device in rolled form. FIG. 5E shows the lighting device in rolled form. FIG. 6A shows an unfolded star-shaped illumination device. FIG. 6B shows an unfolded star-shaped illuminator. FIG. 6C shows an unfolded star-shaped illuminator. FIG. 6D shows an unfolded star-shaped illuminator. FIG. 7A shows a lighting device consisting of remoldable triangular components. FIG. 7B shows a lighting device consisting of remoldable triangular components. FIG. 7C shows a lighting device consisting of remoldable triangular components. FIG. 8A shows a diagram of a flexible solar powered lamp. FIG. 8B shows a diagram of a flexible solar powered lamp. FIG. 8C shows a diagram of a flexible solar powered lamp. FIG. 9A shows a plan view of an inflatable lamp cube with electrical and data input/output ports. FIG. 9B shows an exploded view of an inflatable lamp cube with electrical and data input/output ports. FIG. 10A shows different views of an embodiment of a collapsible solar powered lamp with side access to input/output ports. FIG. 10B shows different views of an embodiment of a collapsible solar powered lamp with side access to input/output ports. FIG. 10C shows different views of an embodiment of a collapsible solar powered lamp with side access to input/output ports. FIG. 11 shows an exemplary electrical schematic of a solar powered lamp. FIG. 12 is a flow chart showing the steps of using the lighting and charging device.

This document generally describes a foldable device that uses solar power to charge and light other devices and receive charging from other devices such as smartphones. The collapsible devices described herein can take the form of lamps when they are inflated, and are hollow (air-filled) to help distribute the light projected from the LEDs within their volume. An interior volume can be defined (and can include notches, frosting, or other features on the housing wall to better diffuse light from the housing). Such expanded shapes of devices include, for example, rectangular boxes such as cubes with hollow interior volumes, inflatable stars, panels that can be rolled into multisided tubes, and truncated cones, among other forms. can take the form of In the example of a rectangular box, such that the box can be folded flat (i.e., the corners away from the notch can be pushed toward each other until they nearly touch in the folded state, so that the box or other so that the corners at opposite ends of the diagonal indentation can be pushed apart from each other until they are at opposite ends of the flat panel that is formed when the three-dimensional shape of is folded in two dimensions) , the opposing sidewalls of the housing can be at least partially open, such as along a diagonal line from one corner to the opposing corner. Elastic straps, such as round or flat cords, are attached at each end to the corner edges of the box away from the score line without the need to pull on the housing other than upon initial opening and closing (i.e., to pull the score line closed). straps) can help bias certain configurations toward their open or closed position to assist the user in opening and closing the lamp housing. Thus, the housing can effectively pop open in response to limited actuation force applied by the user. In the rectangular box example, the box is prevented from moving past its open position by locking the sidewalls on both sides of the notch into contact with each other when in its fully inflated box configuration. can be done. Other mechanisms can also be attached to the movable portion of the housing to bias the housing towards the open or closed configuration as desired.

The solar panels can be placed on one or more sides of a box (or other form of lamp), each solar panel being flat with a corresponding battery and circuit board on which one or more LEDs are mounted. can be arranged in a sandwich (in which case the associated solar panel, battery and circuit board can each be approximately the same size and shape as each other when viewed from above), e.g. Solar panel, then battery, then circuit board, then circuit board, although two or more of these layers can be combined, such as by placing the relevant components next to each other when viewed from the outside. It can be stacked as an LED for illuminating lamps. The sandwich can be sealed watertight and/or airtight from the outside and from each other with a transparent cover over the solar panel and a transparent panel between the LED and the interior of the housing.

The device may further include a sealable pouch, e.g. covering two panels of the box that are not scored and not covered with solar panels, the pouch being able to hold a smartphone or other electronic device when the lamp device is folded. It can be sized to receive a device. For example, in one embodiment, when the lamp device is folded into a flat rectangle, one side of the rectangle can be solar panels from two adjacent sides of the previous cube, and the opposite side of the flat rectangle. can be a smart phone or other electronic device in the pouch. The pouch can be sealed, for example, by a seam that engages from one side of the pouch to the other along the entire edge of the pouch, similar to a zip lock or similar sandwich bag closure. A power plug is placed inside the pouch so that a smartphone (or other electrical and electronic device) can be attached to the plug, slid into the pouch, and the pouch sealed (e.g., via a zip-lock plastic seal). can be placed in Although a particular lamp may be configured to support only one of these functions and not the other, the plug may be capable of or carry both power and data (e.g. , USB). In other examples, such as when the lamp is equipped with solid-state memory storage, the plug can provide and receive data (e.g., when a traveler uses the lamp to store photos from a smart phone). ), can provide and receive power.

Additionally, one or more magnets can be integrated into the lamp housing (eg, placed in a closed pocket of the housing or glued to the sheets of material that make up the walls of the housing). Also, one or more magnets can be used to hold the lamp to a metal object (e.g., to easily hang the lamp from a steel beam or attach it to an electrical panel door). Thus, the one or more magnets can be sized to hold a weight sufficiently greater than the weight of the lamp against normal steel material so that the lamp does not easily fall off. Such magnets can additionally or alternatively be used to hold the lamp in an expanded or folded state (or both). For example, in the case of a tube-wound lamp, magnets can be incorporated at each of the opposite ends of the sheet that makes up the lamp, and these two magnets will energize when the sheet is wound and the ends are close together. can mesh with each other. Alternatively, snaps, straps and other structures, such as a short plastic strap glued at one end, can be used to join one end of the sheets making up the housing to the other end of the sheet, allowing the lamp to be in an inflated configuration. It can be bonded or snapped to the other end for retention.

The device (whether in this rectangular box form or other forms discussed below) can also include electronic sensor packages such as GPS packages and motion sensor packages. Such sensor packages can collect data and display it to the user via a display on the lamp or via transmission to an external device, and/or such as built-in WiFi or cellular data connections in the lamp. and/or can be placed in a watertight compartment of the lamp and can power a MiFi type device and provide it with data from the lamp, or simply power a MiFi type device and transmit the collected data to other devices or can be transferred to the system. In this way, for example, hikers can use the lamps to collect GPS data, transmit GPS data (e.g., automatically notify family members as to where they are), MiFi type devices commonly used for this purpose can be used, all of which can be powered using the solar cells of the lamps.

Referring now to the drawings in more detail, FIGS. 1A-1C show lighting and charging device 100 in an expanded configuration. Here the device 100 is shown as a lamp having a housing 104 in the form of an expanded hollow cube (in the particular form of a rectangular box with all twelve edges of essentially equal length). Enclosure 104 includes six panels between its edges, with two adjacent edges including solar panels 102A, 102B. The solar panels 102A, 102B in this example are shown in the top and left adjacent panels. This example allows them and their associated electronic devices to be easily connected to each other across the corners they share.

The side-by-side placement of solar panels 102A, 102B also allows both panels 102A, 102B to be exposed to sunlight in a number of different configurations. For example, in the configuration of FIG. 1A, device 100 can be suspended from tab 134, which places each solar panel 102A, 102B at a 45 degree angle to vertical (each solar panel 102A, 102B). 102B are facing opposite directions). As a result, when device 100 remains suspended outwardly by tabs 134, both panels will tilt upwards toward the sun, and at least one panel will tilt toward the sun. When the device 100 is folded, both solar panels 102A, 102B are on the same side of the device 100, coplanar with each other, and adjacent to each other, as shown in FIG. 1C. By placing two sets of solar panels 102A, 102B and associated electronics (e.g. LEDs with associated sheet batteries and circuit boards) in adjacent panels, either solar panel 102A or 102B can The two sets can be conveniently interconnected together so that either battery can power the lights in either inner portion of the two panels. Also, a single electronic controller can be provided to control the operation of the mechanisms in both panels, the electrical connections merely needing to pass through the corners of the device 100 that they share with each other. do not have.

The housing 104 is constructed of layers of flexible plastic sheets per panel, and each panel can have one or more layers. A single layer can be provided on the panel that only defines one wall of the housing 104, but multiple layers can be used if the panel serves a function such as housing electronic devices, The panel should physically separate and house the electronics from both the outside of device 100 and the inside of housing 104 . The layers for adjacent panels are aligned along the line (corner) between the two solar panels 102A, 102B to form the hinge 106 and at the other edge of the housing 104 that is parallel to the hinge 106. It may be welded, or a single sheet of plastic may be wrapped around one to four of the walls of housing 104 . Comparing FIG. 1A in the inflated state with FIG. 1C in the collapsed state shows that two hinges, including hinge 106, are open from 90 degrees to 180 degrees and two are closed from 90 degrees to 0 degrees. Between the hinges discussed herein, where the panel has multiple layers, the sheets, which are layers, can form pockets. The pocket can hold various electronic devices (whether permanent electronic devices that are part of the device 100, such as solar panels, or charging stations) so that the device 100 can be inherently watertight during operation. A temporary electronic device, such as a smart phone, placed in a sealable pouch for storage purposes) can be placed and sealed. In this example, solar cells, batteries, circuit boards, electronic devices, and LEDs may be contained between layers forming pockets that are permanently sealed (from the surroundings) on either side of device 100 (those pockets may or may not be sealed from each other). The two panels on the opposite side of the solar cell panel are separated from one or more layers of sealable and non-sealable layers to form a single large pocket and accommodate an electronic device such as a smart phone. may be formed. The remaining panels on the sides of device 100 may be constructed from a single layer of flexible plastic (e.g., with an open score line diagonally across each panel, and each score line on the opposite panel). It may be configured to expand and contract by being parallel to the object, or by using a particularly elastic material for the side panels).

By comparing FIG. 1A with FIG. 1B, the operation of device 100 can be seen as it first begins to move from the expanded state to the collapsed state. There, in the side wall of the housing 104, a diagonal notch 108 or seam runs from one lateral edge to the other (from upper left to lower right in the figure and parallel to the opposite panel not visible in the figure). notches) are arranged. Although referred to as "notches" 108, such description is such that the sides of housing 104 can move from a square to a diamond shape to a flat shape (FIG. 1C). It is meant only to indicate that the openings are configured on enough opposite sides that the opposite surfaces of the are apart from each other. As shown here, a notch is a space that extends diagonally from one corner of the cube to the opposite corner (and parallel notches on the opposite panel of the cube) on the same panel or face of the cube. Folding of housing 104 can be encouraged by pushing hinge 106 toward its opposite hinge (diagonally opposed across housing 104). Such motion is connected between the other side corners of the housing 104 (the side corners parallel to the hinge 106 corner and the opposite corner) and naturally pulls those corners toward each other. It can be internally resisted by the device 100 via elastic straps 112 in the form of flat cords.

Also, the two portions of the panel on either side of the notch 108 are centered and inside the housing 104 as they move apart and the other edge moves together to begin folding the two panels. The triangular angle on the opposite side of the panel section from the centerline of the side of the panel section that abuts the notch (between the two edges that are not hinges 106 in effect and the opposite edge) for snug folding. )) can be creased along their centerline 107 .

Inflation of device 100 is accomplished in the opposite manner by the user pulling hinge 106 and its opposite edges away from each other and/or pushing the other side edges toward each other. In situations where elastic straps 112 are provided inside housing 104 to help bias device 100 toward its expanded state, little force is required.

Also, as shown in FIG. 1B, stops in the form of tabs 114 are provided on each of the triangular half-panels on the side panels of housing 104 . The tabs 114 may be integral parts of the half panels that extend slightly from the sides of each half panel and are located on portions of each half panel that are not aligned with each other. As such, tabs 114 for one half panel are at different locations along score 108 and tabs 114 for the other half panel. Tabs 114 can be positioned so that they meet when housing 104 is inflated to better lock housing 104 in its expanded configuration. Tabs 114 are provided (e.g., loose ends) to hook on the opposite triangular panel when device 100 is fully inflated and to prevent device 100 from flattening in the opposite configuration. Extends slightly into or out of housing 104 (by naturally flexing the plastic panel at the edges).

In this way, the light can then be distributed fairly evenly by the mechanism that shines the light inside the cubic enclosure 104 (or other hollow three-dimensional shape) and exits the enclosure 104 into the room. A device 100 is provided that can scatter light from at least two or four walls of a cube, including walls that can be scored or frosted to increase the amount of light and smooth it out. can be The device 100 can then be folded by the user (e.g., after the device 100 has charged its batteries all day long, and then used inflated and used as a lantern and/or charger for electronic devices at dusk). can be placed on a backpack, on clothing, on the exterior wall of a building, or elsewhere in the daytime), flattened for ease of shipping or other transport with the solar panel exposed It can be easily folded into a compact shape. The device 100 described and shown in FIGS. 1A-1C also includes mechanisms for powering and/or receiving power from devices external to the device, such as smartphones, tablets, and other lanterns. can be provided. Specific mechanisms for such charging are described in more detail in the following figures.

FIG. 1D shows a sealable pocket 124 on one side of lighting and charging device 100 . In this example, the pocket 124 is on the opposite side of the side shown in FIG. 1C (eg, on the two panels not visible in FIGS. 1A-1C) and two panels of the box that do not contain the solar panels 102A, 102B. extends along the entire length of the In other words, the two sheets for housing 104 (which may be an inner sheet and an outer sheet) are not welded together at the edges opposite hinge 106, so the sheets close outward. It can, but forms an open pocket across the two panels of device 100 .

Pocket 124 is now clearly shown as containing a pair of electrical accessory plugs 122 . The plug 122 can take the form of, for example, a USB or Lightning male or female plug and can be connected to a regular device such as an iPhone® smartphone, iPad® tablet, or a smartphone or tablet running the Android operating system. It is configured to plug into the power and data ports of various smartphones or other devices that require efficient charging. Such port plugs are designed so that they can provide both charging and data transfer (eg, a USB cable with one end plugged into one computing device and the other end plugged into another computing device). ), but in certain applications can only be used to provide power or charge. As such, they are referred to herein as power/data connectors. In certain implementations, the plug can take the physical form of a power/data connector (e.g., USB), but with connecting wires that support only one of two functions, such as power delivery. good too.

The plug 122 in certain embodiments may only provide (and/or receive) power to such power and data ports on the device, or may also provide data communication. For example, a controller (not shown) that is part of device 100 controls how electricity is applied from solar panels 102A, 102B to flat batteries in device 100, and how electricity is applied from the batteries to the LEDs. can do. The controller also controls how power is applied from the panels 102A, 102B and/or batteries to external devices, and potentially how power received from external devices is applied to batteries and/or LEDs within device 100. can do. Specific techniques for lighting and charging control and operation for external devices are described in more detail below and are applicable to the various physical forms of lanterns discussed in this document.

A sealable opening 120 is shown at one edge (one short side) of pocket 124 . The sealable openings 120 may take the form of opposing ridges that interlock on the two flexible plastic sheets that make up the housing 104 in place, such as in the form of a zip-lock housing. can. Thus, a device such as a smart phone can be inserted into pocket 124 through opening 120 attached to a suitable plug 122, and opening 120 can be zipped closed. The smart phone can then be charged within the watertight protection of the pocket 124 for the amount of time necessary to transfer the proper amount of electricity to enable proper operation of the smart phone.

Pouch 124 is made up of two cubic It may extend the length of the two panels and the pocket 124 may be left open at the edge corner between those two panels. The panels that make up the outer wall of the pocket are sealed (e.g., thermally sealed) and can define an outer wall of the interior space inside the housing 104 when the housing 104 is inflated. Also, in some embodiments, the outer layer of plastic in the pocket 124 is a material that does not interfere with the use of the touch screen display so that the user can operate the smartphone while it is still sealed inside the pocket 124. may be formed from

FIG. 1E is an exploded view of lighting and charging device 100. FIG. Generally, this diagram shows the various layers that can make up the housing 104, but in an actual implementation, the layers are separated along the line of the hinge 106 (see FIG. 1A) and at the hinge 106. At certain locations such as other edges of parallel housing 104 (basically at all 90 degree corners of the cube except where the pocket extends across the two panels) (e.g., adhesive or bonded together by heat or sonic welding).

Device 100 is constructed from various layers including layers of plastic sheets cut around them to achieve the functionality described above. The layers may be arranged during manufacture in a manner similar to that shown in the images, the sheets may be joined to hold the various components in place, and the planar structure may be the previous It may have certain edges that are folded and then joined to form the fully inflated/collapsed cube shown in the figure. For example, the top layer 140 is rectangular in shape and has four panels of approximately equal size, with tabs 146 that overlap and adhere to opposite panels when the layer 140 is formed into a box during manufacture. Lower layer 142 also includes four square panels each corresponding to one of the panels of upper layer 140 . Bottom layer 142 also includes triangular panels 146 extending on either side of the central two square panels of bottom layer 142 (they could also extend from top layer 140 as well). These triangular panels 146 can form the sides of the housing 104 when the device 100 is in its expanded configuration as a cube. Each such triangular panel 146 includes a compression line 148 (corresponding to centerline 107 in the above figures) at its center to facilitate folding of the associated panel along that line. The line may be formed by partially scoring the panel at that location, by partially melting through the panel at that location, or by forming the panel such that the sheet is thinner at the compression line 148. can be formed.

Located between top layer 140 and bottom layer 142, each of which is a flat plastic sheet, is a relatively flat (not as flat as the sheet) electronic layer 150. FIG. Electronic layer 150 can be disposed in one or more panels of device 100, here disposed in two panels as two separate physical structures. The electronic layer 150 can include solar panels, batteries, one or more printed circuit boards, LEDs, switches, and associated circuitry (eg, one or more microprocessors) for operating lighting and charging functions. An example of an electronic device is shown in the circuit diagram of FIG. 11 below. The electronic layer 150 can be sealed during the manufacturing process by arranging the layers as shown and sealing two plastic sheets together around part or all of the panel. . Generally, the side edges are all sealed, whereas the edge between two solar panels (or at least leaves a passage for wiring, the remaining edges are sealed, etc.) and its Certain lateral edges may not be sealed, such as edges opposite edges (because sealing prevents a smartphone or other device from extending the entire length of the protective pouch).

FIG. 1F shows the lamp 100 after fabrication from one side. The solar panels 102A, 102B and the remainder of the underlying electronic assembly 150 are shown in the top and left panels of the lamp 100. FIG. The opening of indentation 108 is also shown, but lamp 100 is essentially closed here due to its inflated state. Tabs 114 in FIGS. 1B and 1C are not shown in this particular embodiment, but they also prevent the box from unfolding excessively and then collapsing in a direction opposite its normal direction. can be included to help prevent Here plug 122 is shown extending from panel 102B on one side of lamp 100 to the other. The pocket holding panel 102B can have a watertight seal from the pocket holding panel 102A and the pocket (not shown) surrounding plug 122, but is watertight from the outside of lamp 100 and from other pockets. Even if watertight, each such pocket can be electrically connected.

In various embodiments, the lamp 100 described herein and other forms of lamps described below can wirelessly interact with a computer, such as a smart phone or tablet computer, for example. Such interactions may include the computer obtaining information from lamp 100 and/or providing control signals to lamp 100 . In certain embodiments, the plurality of lamps 100 are arranged, for example, in and around a patio, and using an application on a smartphone, turn on at sunset, change colors in concert, and It may be controlled by a single application running on a single computer, such as by a user who wishes to coordinate the operation of multiple lamps according to user-set goals, such as other such goals.

In one example, the lamp 100 can be equipped with a Bluetooth or other similar wireless network interface and can also turn the entire lamp 100 on or off and turn on certain LEDs (but not all of them) of the lamp 100. or turn off, brighten or dim the lamp 100, change the color of light emitted from the lamp (e.g., if the lamp has red, green, blue, and white/red-white LEDs), or so If not, a microprocessor controller can be provided to enable automatic functions to affect the output of each such lamp 100 .

In certain aspects, the microprocessor provides status information about the lamp, such as, for example, the power level supplied by the solar panel of the lamp 100, or the current charge rate, or the battery within the lamp 100, or a value indicating the current state of charge. Or other data can be obtained. Such data may be provided via a wireless interface to a computer in response to an application on the computer requesting such data. Thus, the application can display values or icons representing data (eg, a number indicating the percentage of charge of the battery, or a red/yellow/green icon that roughly indicates the current state of charge of the battery by its particular color). Applications can also integrate the provided data to derive further values of interest. For example, an application can receive the power level from the solar panel or the current rate of charge, and a value that also indicates the current charge level of the battery, deriving the time it will take to fully charge the battery under current steady state conditions. value can be calculated. Similarly, if the computer is drawing power from the lamp 100, such as through a USB port, the amount of power remaining in the lamp 100 after the computer is fully charged can be calculated and displayed on the computer screen to the user. can be shown in

In other aspects, the computer can generate control signals for lamp 100 via an application running (either in the foreground or background) on the computer. For example, a user of the application can directly control the lamp 100, such as by pressing an icon on the computer screen to turn the lamp 100 on and/or off instantly. Alternatively, the user can touch colors on the color wheel to change the color of the light emitted by lamp 100 . The user can similarly move a slider displayed on the computer's GUI to dim or brighten the lamp 100 .

In this way, the lamp 100 can be wireless both in terms of receiving power and transmitting and receiving data. For example, it may be wired, such as receiving power from a wall outlet or a smartphone, or supplying power to a smartphone, but most often generates power from a solar panel attached as part of the lamp 100. can be operated wirelessly by Certain controls can be performed both locally and remotely (e.g., turning on/off using physical buttons on the lamp 100 and/or via selection of an application on the computing device, etc.). . Other lamps may be controlled only locally or only remotely (e.g. changing light color, etc.). Alternatively, for example, three or four LEDs of lamp 100 may be used to display quartiles of battery charge level while the computing device display displays the same charge level as a number from 0 to 100 ( That is, specific data can be provided locally and remotely, but with different levels of detail, such as a 4-part gradation and a 100-part gradation.

In certain examples, the computing device may obtain data from outside the lamp 100 and use such data to control the lamp 100 . For example, if a user uses an application to turn on one or more lamps at dusk, the computing device can access a GPS unit and an online service that identifies the current dusk time for a particular GPS location. Thus, an application can turn on lamp 100 or lamps at or around that time by using the retrieved dusk time data returned by providing location data to such online services. can be done. In another example, an application can be programmed with the location of lamp 100, such that the application automatically turns on the lamp when the computing device is within a predetermined distance of lamp 100 ( The computing device's position (determined from the GPS unit on the device) relative to lamp 100 (previously registered using an application) can be continuously monitored. In such a situation, a lamp placed in front of the user's home may be lit to "welcome" the user home.

In an additional example, one computing device and application can control multiple lamps. Each lamp can be first paired with a device, and an icon or other visual indicator for each lamp can be displayed by the application when the device is near each such lamp.

Thus, users can use the application to control the lamps 100 (which are not wired together and can be completely separate devices each containing multiple LEDs) individually or in concert. Individual control may be direct, such as by a user pressing an icon representing a particular one of a plurality of lamps to turn on or off such selected lamps. Individual control can also be indirect, such as by having scheduled on-off times set and stored separately for each lamp. For example, one lamp may turn on at 7:00 pm and another lamp may turn on at 7:30 pm.

For coordinated control, the change of each light can be simultaneous or sequential. For example, a user can use an application to group multiple lights and then select a color on a color wheel displayed by the application to have each lamp instantly and automatically change to the selected color. be able to. Such simultaneous control can be programmed, such as by having the computing device turn on all the lights at dusk and turn them off a certain number of minutes after dusk. Sequential control can also be programmed, such as by arranging multiple lights in a line (eg, along a drive or walking path). It allows an application to continuously change the color of a lamp, with each successive lamp along the path changing from the previous to create a particular color effect going from one end of the path to the other. Its change is delayed compared to the ramp. As previously mentioned, the applications and functions described herein are applicable to any form of light described in this document, lamps capable of charging or being charged by an external device, or not. It can also be applied to lamps.

FIG. 2A shows the lighting and charging device 200 in a compressed and folded mobile configuration. Device 200 in this example can be the same or similar to device 100 described with respect to FIGS. 1A-1F. As shown in FIG. 1A, it is compressed both flat into a rectangle and then folded in half into a square (all six panels of the cube are aligned with each other when viewed from the top and parallel to each other when viewed). The single solar panel 202A of the device 200 can be viewed upwards towards the viewer, thus allowing light harvesting and electricity generation for the flat battery housed inside the device 200. can be done. If the device 200 were the same as the device 100 of FIGS. 1A-1F, the other solar panel (not shown) would face downward.

The flexible strap 212 bisects the device and envelops it completely, or at least on its sides and top, keeping it in a very flat and compact configuration (thus not self-expanding). The strap (or at least the layer at the end of the trap) can be formed from a common hook-and-loop fastener material with hooks on one side and loops on the other side. Thus, the strap 212 can be routed back to contact and lock against itself to extend through passages in the tabs 234 and stay tight on the device 200 . The straps 212 also have corresponding snaps, one on the strap 212 and the other on the body of the device 200 or on the other strap, extending in a direction around the device 200 opposite that of the straps 212 . can be held firmly by

Although not shown in detail, the device 200 has one or more power/data connectors, such as in the form of USB or lightning plugs, which can be implemented as described above for the device 100 of FIGS. 1A-1E. , can be held in a pouch with a smartphone.

FIG. 2B shows the lighting and charging device 200 unfolded and unfolded. Here, strap 212 has been pulled away from itself and slid off tab 234 . The fixed end of strap 212 is still permanently attached to another tab 236 to prevent accidental separation from device 200 . In this mode, device 200 is half as thick and twice as wide (in one dimension) as it was in the folded mode of FIG. 2A. Also, the second solar panel 202B is now exposed along with the solar panel 202A, both facing in the same direction as each other. In this mode, the device 200 can be placed on top of a horizontal surface and receive solar energy simultaneously to both solar panels 202A, 202B to maximize its charge. For example, users can leave the device 200 on a table or roof while they are on the move during the day, and return to a fully charged device at the end of the day. Alternatively, for example, the device 200 can be hung in the back of a hiker's backpack with both panels exposed to sunlight.

FIG. 2C shows the lighting and charging device 200 from behind in a folded configuration. This view is the device 200 from FIG. 2B, but flipped over so that the solar panel faces downwards. An additional plastic sheet is on this side of device 100 and is bounded on three edges by a fourth sealable and non-sealable edge (e.g., the edge closest to permanent tab 236 for strap 212). sealed along. A smartphone is shown placed within a pouch so formed (similar to the pouches discussed for FIGS. 1A-1E) to protect the smartphone from getting wet (for example, if it is raining or If the user is a hiker and drops the backpack into a stream or lake), the fourth edge can be snapped on essentially watertight (e.g., via a ziplock or other housing mechanism). can. The plastic surface of the pouch is a material that does not interfere with the operation of the touchscreen on the device so that the user can press their fingers against the outside of the pouch to operate the smartphone held inside the pouch. can be formed from

FIG. 2D shows lighting and charging device 200 in a folded, hanging configuration. Here, rather than resting on a horizontal surface, device 200 can be suspended vertically from straps 212 . Such an approach can be used if some level of light is desired from the device 200 and the device 200 can be hung in a room, but in this configuration the smartphone emits a lot of light. Blocking, the hollow interior of the housing is not available for better light distribution. More generally, this configuration would be used to hang the device 200 from a portion of a backpack such that both solar cells 202A, 202B face outward and can capture sunlight. can be done.

FIG. 2E shows lighting and charging device 200 in expanded form as a lantern from two angles. This is the form the device 200 can take when the user wants the device 200 to produce actual light. The device can be inflated by pulling its opposite compression sides away from each other, and between the edges of the housing furthest from each other when device 200 is collapsed (as described above with respect to FIGS. 1A-1E). can be assisted by the natural contraction of the elastic cords connected to the Also in this example, strap 212 passes through an opening in tab 234 that is sized to receive strap 212 . Such a configuration allows the device 200 to be hung so that the two panels of the housing with the solar panels face up, thus the other two panels face down. As shown in FIG. 2F, their bottom panels are clear with some haze to help distribute the light better down into the room under which the device 200 is suspended. .

FIG. 3 shows a schematic diagram of both sides of the electronic structure for the lighting and charging device. In this example, a pair of solar panels 302A, 302B are shown and may be like panels 102A, 102B, 202A, and 202B described above. Panels 302A, 302B can take a variety of well-known forms and can be either rigid panels or flexible panels, or a combination of the two. Various exemplary positioning arrangements of solar panels are shown with respect to the following figures (eg, FIGS. 4A, 4B, 5A, 5E, 6A-6D, 7A-7C, 8A-8C). been discussed. The electronic devices discussed herein and in other figures above and below can be implemented in each of these configurations, although the shape and position of the electronic assemblies and their underlying components may vary from one configuration to another. Change to match a specific shape. Such shapes or configurations of devices are also implemented with or without external charging capabilities (charging to and from devices external to the lamp or other devices with solar panels and batteries, respectively) discussed herein. can

Panel 302A is slightly smaller than panel 302B so that both can fit on the same size side of the lantern apparatus, but panel 302A is positioned along one periphery of panel 304 and below panel 302A. Space can be left for user control panel 304, which overlaps on the printed circuit board that is parallel to and parallel to panel 302A. Control panel 304 may include one or more input and/or output devices for the lantern operator. For example, the power button 306 can be pressed by the user to light the lantern, can be pressed additional times to light the lantern to different brightness levels, and can be pressed successively to turn the lantern off. Finally cycle back to (and press to turn the lantern back on, then various brightness levels). A status LED 308 may also illuminate when the lantern is charging, when the battery is fully charged, or in other circumstances to inform the user of a particular state of the lantern. LED 308 may also flash at one or more rates to provide additional information to the user. A numeric (eg, 7-segment) display (not shown) may also be provided to indicate the charge level (eg, 0 to 100% scale) of the battery within the device.

A pair of plugs 310, such as a USB and Lightning plug, are connected by wires 312 to panel 302A (or more specifically to the printed circuit board to which panel 302A is also connected), captured by panels 302A and 302B and then Plugs into a smart phone or other rechargeable device to supply stored power to flat batteries mounted on the backside of panels 302A and 302B, or to receive power from an external device to charge the batteries be able to. Also, control panel 304 and panels 302A and 302B can both be connected to a common printed circuit board with wires 312 and thus electrically interconnected with other components (e.g., control ICs). be able to.

As shown in the bottom example of FIG. 3, the back of panels 302A and 302B are shown (ie, the device is effectively flipped over from the top view). These back surfaces will face inside the hollow center of the lantern when the panel is inserted into the enclosure for the lantern, either directly or through the transparent inner layer that makes up the lantern's inner enclosure. . These back sides, which may be the back sides of a printed circuit board, are attached to the circuit board and connected to be powered by a battery charged by a solar panel, and one that also powers the plug 310 . The above LED lights 314 may be included.

The "sandwich" construction of these flat panels (the solar panel and control panel on the first layer, the printed circuit board on a parallel layer below, and the LEDs on a further lower layer) can take a variety of forms. can be done. For example, a single circuit board can be used for each panel of the device to save money. That single circuit board has each of the electronic components (solar panel, control panel, and lighting LEDs) with the "outer" components (solar panel and control panel) mounted on one side of the circuit board and the circuit board can be mounted with the "inner" component (illumination LED) mounted on the opposite side of the . In order to accommodate the flat battery in such an arrangement without obstructing either the view of the sun of the solar panel or the view of the LEDs inside the lantern, the flat battery should cover less than the entire square shown here. can be covered. For example, as shown in the bottom left of FIG. 3, the battery can be in the rear half of the solar panel and the LEDs can be mounted offset in the other half. Depending on the identified battery needs, such an arrangement can be used on both panels, with the LEDs on opposite sides of each other (e.g., the left outer and right outer sides in FIG. 3, as shown). As such, the right panel can be positioned with the LED in the center, but without the battery.

Figures 4A-4C show a lighting device 400 in the form of a collapsible truncated cone. This solar rechargeable device 400, like the other lamps discussed herein, can be used to illuminate a garden, patio, pool, pathway, or home. It has solar LED circuitry (not shown) integrated into one of its faces 406 which can be its top surface when one of its opposing flat faces (402) is at its base. The solar circuit has bright LEDs that illuminate the interior volume of the lantern 400, a solar panel 408 facing away from the LEDs (not shown), and a PCB (not shown) sandwiched between the two. can be done. The product is designed to fold into a more compact form factor that can be easily transported or stored when not in use.

The device 400 in this example can be constructed from a clear or cloudy flexible plastic material and can be bent at sharp lines such as line 405 to form the eight inclined planes of the device 400. It is shown with two slanted and tapered side panels. The structure shown defines a centerline along which the side panels extend for each of the eight ramped and tapered side panels.

The right-hand view of FIG. 4A shows device 400 in a collapsed state, where when surface 406 is pushed downward (eg, by a user's palm), wall 404 becomes an accordion, thus device 400 folds up. Each side wall 404 is scored or thinned at a point that extends as a horizontal line around the device 400 to allow the face 406 to move downward until it is much shorter than its inflated height. be able to. as the picture shows

In some examples, device 400 is sealed on the inside such that wall 404 and faces 402, 406 can form a sealed interior volume into which inflation air can be received. or it can be sealable and inflatable. In FIG. 4B, a valve 422 is shown for admitting and removing such air. As also shown in FIG. 4B, a pair of devices 400 may be connected together, such as via magnets 420 in corresponding faces 406 . When such a stacked or connected arrangement is made, the power of one device (e.g. holding solar panels and/or batteries) (e.g. holding connectors for external devices such as LEDs or smart phones) electrical connections can also be made between devices, as can be provided to other devices. For example, in this embodiment, the lamps in both figures could hold solar panels, batteries, and LEDs, but their connections maximize power for both by sharing the power stored in their batteries. Allows to provide a single level of light for a period of time.

The electrical connections between these devices 400 and other devices that connect or snap together (whether by mechanical friction-fit connections (such as LEGO blocks) or magnetic connections) are connected to each other. This can be done by two or more conductive extensions abutting one or more conductive pads, or by each device having pads extending outwardly from the surface and contacting other pads extending outwardly from the surface of the other lamp. , the pads can bend closely so that they are flush with the surface when the devices are pressed together (eg, by magnetic forces). Other suitable electrical connectors also have the general purpose of ensuring that they connect and disconnect from each other via the same user movement that brings the devices into contact with each other, and to allow the user to easily align the devices. can be used so long as one or more electrical circuits can be constructed reliably and conveniently in such a way that the alignment of such devices is also similar to the alignment of electrical contacts. and bring connections.

Device 400 includes a rechargeable battery (similar to those described above for other forms of lamps, although with a different shape to match the shape of device 400), LEDs, and components for regulating charging. , and a solar LED circuit (not shown) having a solar panel or solar cell connected to the circuit board. The rechargeable battery can be recharged by the solar panel 408 or possibly by an additional power input such as a micro-USB input (connected in the manner described above and below for other embodiments). The circuit can have one or more push buttons or switches to control the LEDs and check battery power. The circuit can also have an automatic sensor that automatically turns on the LED when it gets dark, making it convenient to use the lantern to illuminate a walkway or pool at night. The LED shines within the body and is semi-diffuse or partially diffuse through the surface of the main material (eg, by a material that has a smoky or hazy appearance).

When the device is tapered in this way, solar panels may be placed on one (or both) of the opposing faces/edges, which collect sunlight when placed face up. can light. The panel on the small side/edge 406 can make the device more stable when it is placed on a surface and also allows the light to spread upwards and outwards more effectively. A larger panel on face/edge 402 allows the device to capture more sunlight through the larger panel and better diffuse the light downwards, thus making it particularly suitable for sidewalk lighting. can do.

As shown, the device 400 is designed to fold along its centerline for easy storage or transportation when not in use or being charged. For example, if someone wants to put away the device 400 for the winter, he or she can easily fold the product and put it in storage. In addition, packaging also reduces shipping costs during shipping and facilitates carrying one or more devices 400 in or on a backpack or other storage item. As mentioned above, the folding can occur by placing perimeter indentations or other weak points at different heights around the edge of the lamp, the indentations along which the lamp is folded along its centerline. Sometimes it can be off center relative to the wall thickness so that all other seams are biased to bend in the opposite direction to form the structure shown on the right side of FIG. 4A.

To allow air to flow in and out when the lamp is folded or inflated (whether air movement causes expansion/contraction or expansion/contraction causes air movement in and out of the housing), the lamp One or more openings can be disposed in the walls of the chamber formed therein. If the lamp is designed to be inflatable, an openable valve (eg, valve 422) (such as a floating raft valve) can be provided to seal air within the housing. The walls facing the LEDs that illuminate the housing can, in some embodiments, be partially or fully reflective or (e.g., suspended case) can be essentially transparent (although perhaps cloudy) to allow light to exit from the bottom of the lamp.

The material that can be used for the housing is silicone material, but it can also be other kinds of soft plastic materials such as EVA, TPU, rubber or other mixtures. These materials can also be used for the walls and substrates of other devices discussed above and below in the figures. The product is folded as the sidewalls have varying thicknesses or densities to allow for "folding" as the sidewalls are folded together. The same effect can be achieved with a fabric outside and a rigid frame to provide structure to the fabric. The frame can have hinges so that it can be folded.

5A-5E show lighting device 500 in a rolled configuration. This solar rechargeable lamp and phone charger can be used as a lightweight, easily transportable lantern for camping, backpacking, or other outdoor activities. The very compact design of this device 500 folds or rolls up like a tube and unfolds or rolls out on a flat surface. It can double as a flashlight when folded. Further, it can be wound in one direction for tubes with LEDs facing outward and oppositely for tubes with LEDs facing inward.

Referring now to the drawings more specifically, this design has five solar panels 502 on five different panels of device 100, which are connected together by flexible electrical connections, these connectors being , through the hinges in the wall of the lamp housing between the panels on either side of the device 500 . Each device panel may be formed from a pouch in which a corresponding electronic device (solar panel 502, underlying printed circuit board with appropriate circuitry, and underlying LED lights) is watertightly sealed inside. . The solar panel 502 includes a PCB (and may have a backside in contact with each PCB or may be integrated into one side of each PCB), a rechargeable battery 522 (or multiple batteries 522), multiple LEDs 520, 524 (eg, 1-10, typically evenly and symmetrically spaced), and additional components for regulating current flow to the battery 522 and LEDs 520, 524. . Auxiliary electronics for the LEDs may be located on one side panel of the housing, which may or may not have LEDs in it, while the other panel may have LEDs in it. may have LEDs and a solar panel 502 on it. Each panel has a substantially transparent inner film and seals against the inner film on at least some edges such that the electronic assemblies are sealed from the atmosphere both inside and outside the folded device 500 . and a substantially transparent outer film that is fastened.

The device 500 has one or more USB input ports for recharging the battery by an external power source and one or more USB output ports for charging a phone or other device (or powering in either direction). A USB assembly 508 can be provided having a port that can In this example, the assembly 508 is at the end of one of the side wall segments of the device 500, each segment has a watertight seal on the assembly when the port is not connected to anything. , isosceles triangle in shape and has a matching plastic or rubber cap of the same cross-sectional shape. The segment with assembly 508 can also contain a battery for the device and as a result has no LEDs to illuminate the device. In contrast, the remaining segments can be mostly hollow, their interiors so as to emit light from the two walls of each segment outward from the serrated side of the device 500 when laid flat. can include an LED directed toward the

The device 500 is arranged such that the straps 506 can be wrapped around the segments of the device 500 when they are tightly rolled up, thus holding them in the rolled up position. It can be held in the rolled configuration by a strap 506 having one or more snaps 510, 512 that can mate with corresponding snaps 514 elsewhere along the central portion of 500. FIG.

This shape has five sides and is wound into a pentagonal tube (a tube with a pentagonal cross section), but alternatively the lamp could easily have more or less sides depending on the design. can. The surface of this variation has five ridges on its inside, but it can also be flat or have different extruded cross-sectional shapes.

When deployed, the solar panels 502 can all be exposed to the sun at once (they can all be on the common side of each side panel of the foldable housing and electrically connected to each other). or not, in pockets that are watertight from the outside and optionally from each other). A user can attach the device 500 to a backpack and charge it on the go. Once the device 500 is charged, the user winds it into a tube for use when a lantern is needed or when additional battery backup is needed to recharge a phone or other device. You can put it back in your backpack. In flashlight mode, the device 500 operates like a conventional flashlight (since the extra LED lights at the common end of the device 500 are placed very close to one end of each panel). is focused from one particular end of the . In lantern mode, the LED shines through the surface, which in this design peaks and is diffused throughout the material. The glowing surface can be used to illuminate a tent (e.g., by hanging device 500 via straps 506 from the side walls of the room or the center of the room), or to illuminate a room when power is turned off. can be done. The outer edge of the device 500 has magnets so that the pentagonal tube remains closed and the device 500 can also form a lantern shape when fully deployed.

FIG. 5E shows a version of device 500 in which multiple such devices 500 can be daisy-chained to form a combined device 500 that generates a larger surface area of light. In this example, multiple devices 500 can have a female connector on the top surface and a male connector on the bottom surface so that any device 500 can be snapped above or below any other device in the string. They are connected via snap tabs 530 . Connections may be mechanical only to produce high light, or electrical contacts may e.g. It can also be electrical in that it can be provided internally or at different locations. Using electrical connections, power can be shared between devices 500 in a manner similar to that described above and below (e.g., one device's battery draws power from another device's solar panel). receive or power LED lights of other devices). In certain embodiments, data connections may also be provided between different devices 500, such as carrying control signals that cause each device 500 to change its lighting in response to user input from the first device. can.

The device 500 here can be constructed from various types of solar panels and circuit boards. In one variation, device 500 can be constructed from a flexible solar panel and a flexible circuit board to minimize the overall thickness and weight of the lamp.

The main material for the plastic housing of the lamp can be silicone or other kind of flexible material such as EVA, TPU, PET or fabric. This material is generally transparent or transparent so that light can pass through it (for light collection by a solar panel) or from it (to feed the surrounding atmosphere from an LED). will be translucent. Magnets, snaps, and/or cords may be attached to the lamp, allowing the user to keep it folded in various positions. Solar panels and circuitry may be integrated into the lamp so that they are protected from the elements. A cap covering the port may be arranged for a tight fit to ensure that the port is waterproof.

FIG. 6 shows an unfolded star-shaped illumination device 600 . Paper star lanterns are often used to decorate patios and porches. The design shown in Figure 6 integrates a solar LED circuit into a star to form a sustainable, rechargeable, durable, and waterproof lantern. A solar star is flattened and expanded to form a star shape.

As shown, one face of the star crest 602 has LEDs of a built-in solar panel 608 integrated into it (e.g., in a pocket between two transparent or translucent sheets on opposite sides of the face). have a circuit. The solar panel 608 is positioned facing outwards from the star to collect sunlight, recharge the rechargeable battery and power the LEDs, and peaks from provided hooks (not shown). It can be located on the side of the apex 602 that faces upwards when suspended. Power collected by the solar panel 608 can be provided to LEDs on the PCB behind the solar panel to illuminate the internal volume of the device 600 . Alternatively or additionally, the adjacent outward facing surface of the crest 602 on the same side of the star may have another solar panel or panel of LED lights 604, in which case the LED lights are directed downward. , and the light can be projected outside the device 600 . In other words, the light may be directed inside the top constructed from translucent plastic, or outward from a panel of the device different from the panel on which the solar panel 608 is located, or both. good too. To make the outward direction of the light more uniform, the outer surface of any side carrying the solar panel can be transparent, while the outer layer of any side carrying the light can be frosted.

The PCB, rechargeable battery, LEDs, and other components for regulating current flow are placed on the underside of the solar panel 608 of any given top with solar panels. Components can be connected by wires (eg, PCB traces) to different locations in different design configurations. Additionally, more solar panels 608 can be used if more power is needed. The circuit may be designed to be compact and waterproof (e.g., either inherently or by being placed inside a sealed pocket) and attached to the star to secure it when folded and unfolded. fully integrated into. The LEDs either shine in a star shape (and potentially have them go out of the star or be reflected inside the star housing) or from there by being placed on a top surface that does not have a star. configured to shine directly toward the back side of the A switch can be placed on the PCB so that the user can control the LEDs to check battery power. Solar stars can also have automatic sensors that turn on LEDs when there is movement or when the surrounding environment gets dark enough.

The star may be constructed from a combination of rigid and flexible materials to ensure that it has the necessary structure and remains lightweight and easy to pack when not in use. In this design, the materials used shall be a semi-rigid plastic material to form the frame and a transparent or translucent silicone material to form windows in the frame that allow light to pass through. can be done. In other configurations, the star can be constructed from folded translucent or transparent plastic sheet material or fabric. In all configurations, the lamp can be designed to be packaged flat and then expanded into a fully usable form. When not in use, the user can pack the lamp and store it in their home for when the lamp is needed. In the illustrated configuration, the design is inflatable and deflatable, but not inflatable. However, it can easily be configured to be a closed shell that expands into a star when inflated. Magnets, Velcro®, snaps, or small ties can be used to hold the star in its expanded shape and can be used as well to hold it flat. The material can be cut or scored along the crease to create sharper creases and smoother creases. In some variations, the solar panels can be placed separately from the stars. The stars can be hooked together like string lights, forming electrical connections between them that can vary in distance. The system can then be connected to even larger flat pack battery and solar panel systems.

The various peaks 602 may be permanently connected to each other as a single integrated device (which may have permanent wiring between each peak) or may be connectable and disconnectable. good. Connection may be made, for example, via magnets or mechanical friction connectors placed on the corresponding inner surface of each apex so that the apexes can be easily snapped together and separated by the user. . These physical connectors can also provide top-to-top electrical connections in some implementations. Each apex can implement light collection only (by solar panels), light distribution only (by LEDs), or both. For example, one peak 602 of the star can have solar panels, while the other can have LEDs and get their power supply from the first peak. When users of such stars desire longer illumination or otherwise desire more power, they either exchange the illumination apex for a power apex or an unfinished star (e.g., imperfect stars) can simply add power peaks. Circuitry, including control circuitry within each vertex, can recognize whether an adjacent vertex is supplying power or seeking power, and can adjust accordingly. Also, if the vertices are wired in series, the apex closest to the power source can light itself, and if the other apex determines that insufficient power exists, it will power off to the next apex in the chain. power flow can be blocked. The apexes themselves are also inflatable or deflatable (e.g. , see FIG. 6D), or it can have an interior volume that is sealed from the surroundings and can be inflatable and deflatable.

7A-7C show another form of reconfigurable solar lamp device 400. FIG. This format is generally in the form of a sheet that can be bent along a number of different vertical, horizontal and 45 degree lines, which has only a flexible plastic substrate on these lines and which This is achieved by placing harder materials such as PCBs, batteries, and solar panels away from the folds of the . In a related embodiment, the device 700 is a conventional triangular piece in which multiple three-dimensional triangular pieces are stretched together and can be folded in various directions at each interface between two triangles to create various shapes. can be provided in the form of a "snake cube puzzle".

7A-7C, device 700 in this example is a prototype that uses strips of paper to represent solar panels, PCBs, batteries, and other electrical components. The three vertical rows 702A, 702B, and 702C of device 700 are divided horizontally into four strips, each of which is divided diagonally into four sub-strips. Each sub-piece can include a solar panel, an LED light, or both, along with a PCB and associated circuitry for powering and controlling the lights. A fourth row 804 is divided into four squares and can accommodate four different batteries, which can be wired together (in parallel or in series) and connected with wires and other suitable connectors. can be connected to the triangular sub-pieces via. each triangle can have only a solar panel or only a set of LEDs (the LEDs can face the same side of device 700 as the panels do, opposite sides, or both); Or you can have the solar panel facing one direction and the LEDs facing the other direction in a watertight port (including where each pouch can hold both a solar panel and one or more LEDs).

FIG. 7B shows the device 700 folded in various directions to form a complex shape, sub-pieces 706 can be, for example, pouches holding LEDs and PCBs, the LEDs being 700 may face downward toward the hand of the person holding it, and the same or other sub-piece may include a solar panel facing upward and away from the user's hand. FIG. 7C shows the same device 800, but folded into a much less complicated form. This example has three sides because battery row 704 is pushed behind one of the other rows as part of the folding process. And, in this configuration, device 700 forms a tubular flashlight configuration like device 500 of FIGS. 5A-5E. Other related structures from these figures (eg, straps and LEDs clustered near one edge of the device) can also be implemented with device 800 in a manner similar to that described above. .

Figures 8A-8C show another configuration of a lantern device formed as a flexible sheet. In this example, the solar panel is flexible and the PCB forms wiring traces connecting the different sub-pieces on a flexible plastic substrate that is configured to be flexible or serves as the overall structure of the device 800. excluded by something.

In this example, the device 800 has a flexible PCB 804 on which the LEDs are arranged in small spaced apart areas arranged as squares at a 45 degree angle to the rectangular shape of the sheet substrate 806 . Solar panels 802 were placed in other sub-areas and the ratio of LED sub-areas to solar panel sub-areas produced by each solar panel on a typical day compared to the amount of energy consumed by a typical LED. It can be based on determining the amount of energy, the amount of time illumination is desired, and the amount of light desired.

The mechanism for controlling the illumination of the LEDs is glued and electrically connected to traces on the flexible substrate at the right end of device 900, as shown in FIG. 8A. For example, a film power switch 812 may be depressed by a user to turn an LED on and off, and in some implementations, a microprocessor controller that receives input from switch 812 controls subsequent depressions of switch 812. It may be programmed to cycle the LEDs through different levels of brightness (to lower the brightness of each LED or activate fewer LEDs). Switch 812 may be sealed watertight with the rest of the electronics used in device 800 . A row of indicator lights 814 can, when appropriate, indicate status information such as the current state of charge of the batteries in device 800 (e.g., four lights for a fully charged battery, 1 light, and possibly 1 flashing light for batteries that are about to run out of charge). A thin flat rechargeable battery 808 can be mounted under the surface of this area and under or adjacent to other components. One or more data/power ports 810 are also provided and can be attached in a manner similar to those discussed above and below to power the battery 808 and solar panel 802 or the battery 808 and light 804. can.

FIG. 8B shows the device 800 of FIG. 8A in a flat state from above with the LED lights activated. Here, the ratio of lights (14 total) to solar panels (58 total) is 24%.

FIG. 8C shows the device 800 slightly rolled to demonstrate the flexibility of the substrate or flexible circuit board to which other components are attached. The battery 808 is placed at one end of the device as it is typically some of the least flexible components, and thus placement at the end does not interfere with the overall flexibility of the device 800. Minimize.

In other embodiments where the surface to which the solar panels and lights are mounted is divided into a number of essentially equal areas, the ratio of the space occupied by the lights to the space occupied by the solar panels is 10% to 20%, 20 % to 30%, 30% to 40%, and values of about 20%, about 25%, about 30%, and about 35%; on a typical illumination day in a typical environment to generate enough energy to illuminate the device 800 for a desired period of time, such as for a period of time (e.g., 4, 6, or 8 hours). Based on

Regarding the electrical input or output ports of the lamp, for both the above and below configurations, the input/output ports may be located on the same side of the lamp as the solar panel, or may be located on the other side of the lamp. good too. Each of the various configurations may or may not include, for example, a valve to allow manual inflation and thus inflation of the lamp. The input and output power ports can be protected from external elements with waterproof caps sealed to the surface of the lamp. When the cap is closed, the inner or outer surface of the cap can be slid into or around a corresponding outer or inner surface of a flange attached to the lamp to form a watertight seal. The cap can be opened and closed to expose the input and output ports. In some implementations, the cap has a small tab or door hinge that can be flipped open to access the port. In some implementations, the cap can be twisted or slipped on to expose the port. In some implementations, the cap is a semi-rigid plastic cap that protects the port. In these embodiments, the cap can be removably sealed to one of the lamp surfaces around its edges to form a watertight seal. In some of the embodiments shown in the figures, the cap can be molded from thermoplastic polyurethane (TPU) material and can be sealed to the top surface of the collapsible lantern, also constructed from TPU material. . Adhesives or additional adhesives can be used to secure the components in place. Fusing the material protecting the cap to the material of the lantern can be important to provide a watertight seal and protect the input and/or output ports.

In some implementations, the input and/or output ports can be arranged vertically on the circuit board to minimize the width of the cap, for example as shown in FIGS. 9A-9B. , in which case the USB plug is moved vertically downwards to engage the (connected) port. To reduce the height of the cap, a secondary circuit board or support can be used to lower the port. The input and/or output ports can also be mounted horizontally on the circuit board and can be accessed on the side of the foldable lantern even when the circuit board is oriented horizontally.

A solar powered lamp can include a solar panel, an LED circuit, and a rechargeable battery. The rechargeable battery can be charged by a solar panel, hand crank, 5V USB input, or other power input port that allows the rechargeable battery to be charged by other power sources in addition to the solar panel. etc., can have one or more additional power inputs that can charge them.

In some cases, the USB plug or port may be separate from the main circuit or circuit board and connected by a waterproof cord. In such lamps, the input and output ports are attached to cords extending from the circuit board. By moving the port away from the circuit board, different waterproofing methods can be pursued. As shown in FIGS. 1A-1E, a zip lock pouch can continue to protect the cord, although other protections may be employed. Some ports have waterproof coatings so that the ports can be made waterproof by extending them from the circuit board and sealing around the area attached to the circuit board, They can be freely connected to a power source, to each other, or directly to a telephone without the need for additional housing or protection. The cord can include, for example, micro-USB and other USB ports. The port may be attached to the end of the cord and when not in use the port may be stored in a waterproof pocket on one side of the lamp. The material may also be rolled or folded to form a waterproof seal, or certain types of Velcro or adhesive may also be used to form access points for accessing the ports. good.

There are many different designs for the caps around the ports to waterproof them and form a tight gasket. The cap can be designed to open like a door, slide or twist. The top of the cap can be unscrewed/unscrewed or can be snapped and unsnapped into place. In most cases it includes top and bottom halves that fit together to form a watertight seal. The walls may vary in thickness and configuration to seal together and form a rigid lip to prevent accidental popping.

The port can also be a magnetic charging port which offers the advantage of potentially reducing the need for a cap. In such cases, a tight sticker or seal around the exposed magnetic port can provide the necessary waterproofing. Additionally, advances in waterproof coatings and port designs (such as more waterproof barrel ports) can reduce the need for caps and enclosures that can be exposed and risk water damage to circuits. You can lose your sex.

In the foldable octahedral pyramid shown in FIGS. 4A-4C, there can be magnetic ports at the top. A sticker can cover the circuit board to surround the magnetic port. This allows the port to be properly waterproofed. As noted above, the magnets can provide power input, or in other designs, magnets allow products to be stacked or connected together to extend battery life or share power. can be made possible. A magnet can provide the electrical connection. This electrical connection between products can also be accomplished by metal snaps, tabs, conductive threads, or other forms of connection that allow them to be joined together. The cap and other designs provide an extra level of security to the user and allow the lantern to be fully submerged in water for use as a pool light or underwater light.

FIG. 9A shows a plan view of an exemplary inflatable and collapsible solar-powered lamp (eg, via expansion and contraction of a sealed interior volume), and FIG. 9B shows an exploded view thereof. there is The lamp 900 (also called a lantern or more commonly a device) has a flat rigid top and a flat lid bottom separated by sidewalls having multiple panels to form a cube similar to that of FIGS. 1A-1E. including. The housing of FIGS. 1A-1E was mechanically expanded by popping it open (perhaps with an internally biased telescoping cord), whereas the housing of FIGS. It is inflated and deflated to deflate, which can allow it to float more easily on water when inflated.

Referring now to FIG. 9A, the top surface of lamp 900 is shown, including central solar panel 904 and peripheral region 902 surrounding solar panel 904 on all four sides. Below the perimeter area is electrically connected to the solar panel 904 and can include one or more PCBs that are peripherally shaped like the perimeter area 902 and have conductive traces applied to the PCBs. It can be part 922 (FIG. 9B) of an electronic assembly attached in association.

Mounted on the top of the PCB, as shown in FIG. 9A, is a micro-USB or other form of USB port 912 . The port 912 is surrounded by an attached flexible ring and is in turn coupled by hinges or straps to a flexible cover 914 having a surface that conforms to the shape of the ring's corresponding surface. In this manner, the cover 914 can sealably engage the ring to protect the port 912 from moisture when the cover is closed. The charging light 916 includes LEDs under a protective cover that extends over the top surface of the lamp 900 , a solar panel 904 generating power to charge the rechargeable battery within the lamp 900 and/or the lamp 900 . Illuminates when receiving sufficient light directed into the interior volume. A series of lights 918 , which may be LEDs sealed below the top surface of the lamp 900 and connected to an underlying PCB, may illuminate in response to the user pressing a button 920 . (e.g., 4 of the 4 available lights for full charge, only 1 for very low charge, or first light blinking for very low charge, etc.). More lights can be activated to indicate higher charge.

A power switch 922 then turns the lamp on or off and powers one or more LEDs behind the top panel of the lamp so that they direct light into the open volume inside the lamp 900 . Subsequent depression of switch 922 (also encapsulated below the top plastic sheet) causes continuous depression from the user of lamp 900 to continuously dim the lamp (e.g., decrease the intensity of each LED). , or reducing the number of LEDs lit), etc., to change the illumination mode of the lamp 900 .

Attached to the top of the lamp 900 are a pair of straps 906, 910 that can be stitched, glued, heat sealed, or otherwise attached to the top or sides of the lamp near the top. . The straps 906, 910 may be attached to each other by a pair of corresponding snaps 908 located on each strap (the snaps for strap 910 are not visible because they are on the bottom of strap 910, but are can be seen in FIG. 9B). One or both straps 906, 910 may be positioned at different positions along the length of the associated straps 906, 910 such that the length of the loop formed when the straps 906, 910 are connected together may vary. A plurality of snaps 908 can be provided on the . Lamp 900 can be suspended from a loop formed by straps 906, 910 when straps 906, 910 are bent upward toward the viewer in FIG. 910 can be held to the lamp 900 in a compressed configuration when the lamp 900 is bent downward away from the viewer and connected together below the lamp.

Referring now more specifically to the exploded view of lamp 900 in FIG. 9B, various exemplary layers of lamp 900 can be seen and techniques for manufacturing lamp 900 can be illustrated. In such techniques, pairs of layers may be adhered together, possibly after other components have been placed between those layers, so that the intervening components can be held in place. , can be kept watertight from the environmental conditions surrounding the lamp 900 . Layers that can be adhered together include transparent plastic layers 930 and 934 that can hold a transparent PET layer 932 between them to form a relatively rigid bottom plate for lamp 900 . The sandwich of layers can in turn be connected to a peripheral sleeve 928 of translucent flexible plastic that forms the four walls of the lamp 900 cube when the lamp 900 is inflated.

In the inflated state, the walls of the sleeve 928 are constructed from a single piece of extruded material in this example, but may be constructed from flat sheets having open edges that are sealed together to form a closed sleeve. or may be formed from multiple flat strips, such as four separate strips, one strip for each side panel of lamp 900 .

Sleeve 928 can be a clear plastic sheet, or can be sufficiently transparent so that light from the LEDs directed by sleeve 928 into the interior volume of device 900 can easily travel. It can be sealed in a similar manner as top sheet 926 . By sealing the sleeve 928 around its perimeter at both its top and bottom (eg, by adhesive or heat sealing, or welding or ultrasonic welding), the volume inside the sleeve 928 is expanded as the lamp 900 is expanded. , can be made watertight and airtight so that it can retain its inflation and float.

The top sheet 902 may be sealed at its perimeter to a top sheet 926, which is a watertight pouch for enclosing the PCB 920 and solar panel 904 that can receive sunlight through the transparent window of the top sheet 902. may be formed. Also provided within the pouch is a reflective plate 922 formed in an opening 924 through which the LED mounted on the PCB 920 can be viewed from below. As a result, the LEDs can be directed to illuminate the interior volume of lamp 900 through opening 924 when lamp 900 is expanded or expanded.

In Figures 9A-9B, the data/power port is directly connected to the PCB. The solar panel, PCB, and battery are stacked to minimize overall height. This circuit assembly sits in tray 922 as shown in FIG. 9B. Tray 922 has an area for the battery to sit and holes or openings 924 for the LEDs. The LEDs are arranged in a circle around the battery to maximize further light distribution within the cube. This circuit assembly is sealed between two plastic sheets. Different suitable types of plastics such as PVC, TPU, EVA, silicone can be used. The ports connect to the PCB and protrude from the flat stack of solar panel, battery, tray, and PCB. The ports can be a combination of micro USB, mini USB, USB C, other USB, magnetic, lightning, bi-directional USB, or other combinations.

The ports in FIGS. 9A-9B are perpendicular to the circuit assembly. During the manufacturing process, the outer layer of plastic has holes drilled where the ports can protrude. In the process of assembling the lamp, as a first step, the port cap is sealed to the outer layer of plastic. This outer layer and sealed port cap is then carefully placed over the circuit, lining up the ports inside the cap and hole. See Figure 9B. A lower layer is then placed on the opposite side of the circuit assembly. In some variations more layers can be used. A lower layer and an added upper layer sandwich the circuit. This entire assembly is then placed into a manufacturing tool. The tool can have a hole in the top to allow the port cap to protrude to achieve a tight, flat seal. The tool seals together layers of plastic around the outer edges of the circuit assembly.

The outer layer is also sealed to the sides of the cube and the bottom of the cube to form a semi-enclosed volume. Port caps are a simple and effective way to seal any port or switch you need to access. The ports can be 5V, 1 amp, 2 amps, or higher to control charging for different electronic devices. Higher or lower voltage outputs are also possible depending on the size of the battery and solar panel.

In the above detailed description, the outer layer on the circuit was composed of two separate elements, the port cap and the plastic sheet. These two elements are simply constructed as one element by molding the two together as one unitary mould, or by using other types of seals or zip locks to access the ports. can be Magnetic and waterproof ports do not necessarily require the same type of port cap.

Holes can be cut in the material and the material can be sealed directly to the solar panel or PCB coating, or adhesives or additional gaskets can be used to form a watertight seal around the magnetic ports (if such magnetic ports are used). Waterproof ports are also available, eliminating the need for port caps. For waterproof ports, adhesives or careful seams must be implemented to protect the circuitry.

In FIG. 9A the port cap is hollow and the port is exposed when the cap is open. The top of the cap fits into the bottom, waterproofing the port. The ports can be directly connected to the main PCB, or can be located on smaller PCBs that are in turn connected to the main PCB. Wires or cables can also be used to keep the PCB away from the port.

Solar panels can be coated with multiple materials, for example epoxy, ETFE, or PET. These coatings can be fused directly to the port cap, eliminating the need for a top layer. In such an embodiment, a touch sensor switch can be used directly under the coating to waterproof the switch. Other types of coatings or adhesive stickers can also be used to protect the components. In order to reduce the thickness, the solar cells can be attached directly to a very thin PCB. Also, a thin Lithium-Ion battery or other type of battery, or a large capacitor can be placed directly underneath the PCB, and can be placed on other sides as well. The edge of the coating that covers the solar panel is applied to the edge of the solar panel to form an edge that can then be directly sealed to the volume to eliminate the need for multiple layers of sandwiching circuitry. It can extend beyond the edge.

Other specific implementations with ports can also be used. For example, both a USB input port (or lightning port) and a USB output port can be provided under a single cap of one lamp to provide a convenient mechanism for charging to and from the lamp. can. In such an embodiment, for lamps with a single port, the manufacturer need construct only one cover part that is used for both its single-port lamps and its multi-port lamps. Although one may want to use an oversized cover for the port, the cover may need to be wider than it would be if there was only a single port underneath. In some cases (for example, a lamp can be charged by one power source, but can provide charging to multiple external devices via USB cables plugged into multiple output ports). A pair of input or output ports can be provided, or a pair of single ports of one type and the other can be provided. Instead of a plastic removable cap, in one embodiment of the port arrangement shown in FIG. 9A, a ziplock or similar seal may be provided over one or more ports. In such an embodiment, the seam may open to the side of the lamp and the port may be open so that the USB plug can be inserted and plugged in from the side rather than from the top as shown in FIG. 9A. It may lie substantially flat and parallel to the PCB.

With each form of light herein, a bank of solar panels can be provided external to the lamp, the lamp having no solar panels itself or a small number of solar panels (e.g., one or two ). A solar panel external to the lamp can be wired directly to the lamp to power it and/or connected to the battery to charge the battery over time even if it is not already connected to the lamp. and, if the lamp is connected to a battery and an external solar cell, the lamp can be powered via the battery. Similarly, two or more solar-powered lamps of any suitable physical type can be electrically connected together so that they can share stored power with each other.

Figures 10A-10C show an inflatable solar powered lamp 1000 in the form of an inflatable bag. Like the other lamps described above, the lamp 1000 generally includes an electronic lamp within a watertight pouch that receives sunlight from outside the lamp 1000 and directs light from the LED light into an inflatable and contractible volume inside the lamp. Can include assembly. Additionally, the electronic assembly can be provided with one or more USB, Lightning, or other data/power ports.

10A-10C, the lamp 1000 includes a handle 1004 at its upper end and an inflatable bag 1020 below it defining an empty interior volume when inflated and facing each other. As the side walls of the expanding bag move toward each other and meet in many places, they have little volume when deflated. The entire bag can be constructed from two matching rectangular plastic sheets, joined at their side edges to a pair of side panels 1020 that cover the interior of the lamp 1000 when the lamp 1000 is contracted. It is scored in the middle so that it folds inwards into the volume. The bottom panel 1022 may constitute a fifth wall that defines an interior volume, and is scored to fold into a space that allows the lamp 1000 to lie flat to a practical degree when folded. may be attached. An air valve 1002 can be provided on one side of the lamp 1000 to allow air to flow in and out of the interior volume.

The handle 1004 can be split into two separate parts, as shown most clearly in FIG. 10C, and the two parts can be snapped or unsnapped together. Such action allows the user to wrap handle 1004 around a pipe, closed-loop strap, or other structure for hanging lamp 1000, such as near the ceiling of the room to be illuminated.

As with the other lamps described above, an electronic assembly 1006 is shown covered by a solar panel 1008 facing the exterior of the lamp 1000 via a transparent protective cover that keeps the electronic assembly 1006 watertight from the exterior of the lamp 1000. It is Below the solar panel 1008 may be a PCB that provides functionality via microcontrollers and other circuits accessed from the side of the electronic assembly. For example, the power switch 1010 (1014 in FIG. 10C) can be depressed by the user to turn the LEDs on or off, with successive depressions of such depressions until they are turned off. The LED can be dimmed gradually over several cycles (eg, turned off on four presses, then turned on by the next press, etc.). A series of indicator lights 1012 can provide an indication of the state of charge of the rechargeable battery within the lamp 1000 that is charged by the solar panel 1008 . The indication may occur in response to a user pressing test switch 1014, with more light indicating a higher state of charge.

And in this way, many forms of solar-powered lamps have been discussed, including the ability to charge to and/or from an external device via a common charging port such as a USB port (e.g., cubes, pillows/bags that are roughly triangular when viewed from the side, truncated cones, and stars). Appropriate circuitry (eg, FIG. 11) may be provided for each to allow solar energy to be used to charge the battery and/or power the LED lights. Light may illuminate an internal volume formed when a particular lamp is moved (whether mechanically or via expansion) into an expanded configuration. And, multiple components can be provided to help the user interact with the lamp and understand the current state of the lamp. The lamp is particularly useful when used to charge other devices that do not have solar charging, such as smart phones, or when charged from an external power source, such as by being plugged into a 120V AC power supply via a USB adapter. can do.

FIG. 11 shows an exemplary electrical schematic of a solar powered lamp circuit 1100. As shown in FIG. Generally, this schematic is generated by a plurality of solar cells (whether as output power from the device in which this circuit is used or as input to such a device) and one or more It shows the electronics and connections for passing and regulating power that can be used by any device that can connect to the LED and USB charging port.

Referring now specifically to the particular components depicted in the figure, a plurality of solar panels 1136 (grounded at ground 1138) are shown on the far right to provide current to the rest of the depicted circuit. connected in series to supply The solar panel 1136 is in turn connected to an LED 1132 (with a diode) and associated resistor 1134 that indicates (by lighting) to the user that the panel is supplying charge to the circuit. When the panel is not, the battery 1112 provides power and diode D1 1118 ensures that power flows in the correct direction from the panel and/or battery to the rest of the circuit. Light sensor LS 1120 is required (along with associated resistor 1122) so that the circuit is closed (and the lamp is energized) only when the light sensor detects lack of light (e.g., at night or indoors). may be provided according to Additional sets of resistors 1124, 1126, 1128, 1130 can also be provided and connected to solar related inputs while traces controlled by light sensor 1120 power one or more LED lights. (and can be passed through a manual switch (not shown) to allow power to flow).

Battery charging can be controlled via ports BAT and PRG of a dedicated integrated circuit 1104, such as the TP4056 standalone linear Li-Ion battery charger with thermal regulation. Such an integrated circuit can function as a constant current/constant voltage linear charger for single cell lithium ion batteries, but multi-cell batteries can also be used. Thermal feedback regulates charge current and limits die temperature during high power operation or high ambient temperature. The charging voltage in this example is fixed at 4.2V and the charging current can be programmed externally by a single resistor as shown here. After reaching the final float voltage, the chip can terminate the charge cycle when the charge current drops to 1/10 of the programmed value. Chip 1104 may also include a current monitor, undervoltage lockout, automatic recharge, and two status pins for indicating end of charge and presence of input voltage.

Again in this example, an external USB port 1106 is provided, which in certain implementations may be a port for charging a battery, a port for charging an external device using the battery, or both. Also, multiple ports with similar functionality may be provided, and in certain implementations may transfer data and power (e.g., if the lamp has integrated flash storage), or simply transfer data rather than data. It may also provide power transfer. USB port 1106 may take any suitable standardized form and may be in USB format or other wired power transfer protocol (eg, Lightning port) for charging portable electronic devices. USB port 1106 (with an associated ground) can be controlled by USB controller 1102, which can take the form of a USB micro or other similar controller for data/power connection systems.

Variations of the particular circuit shown here may be provided, and variable numbers of solar cells, LEDs, and batteries may be used. Various indicator lights are also provided to indicate when the lamp is charging or discharging and to indicate charging or discharging status via each of one or more USB or similar power connectors provided with the lamp. good too.

Thus, in this way, the circuits shown here and similar circuits can be fabricated on a PCB to provide power (and potentially data over the same port, for example if the lamp contains flash memory or similar functionality). ), as well as a cost-effective and compact implementation that can be directly or indirectly connected to solar cells, one or more batteries, and LEDs. Such an arrangement can take up minimal space and can be very flat, especially so that it can be mounted beside or behind the solar panel (and behind the LEDs on the opposite side). , can be very thin (e.g., less than 1/8 or 1/4 inch), thus allowing electronic devices to capture sunlight and efficiently distribute the generated light, while the lamp moisture and other conditions within the housing of the lamp (e.g., where condensation may occur naturally and/or where moisture may become trapped when the lamp is expanded in the mouth) and moisture and other conditions outside the lamp. can be easily placed in a watertight pocket that can be formed to protect the electronic device from the condition of

FIG. 12 is a flow chart showing the steps of using the lighting and charging device. In general, the steps shown here involve transitioning the lantern from a compressed, folded state for charging to an expanded state for lighting, and vice versa. For example, this process can occur when it starts to get dark in the evening and light is needed by the user of the lantern, and then continue until morning (the general inverse of evening) when the light is no longer needed. can be done.

The process begins at box 1202, where the user picks up the lighting device (eg, FIG. 2A) folded onto itself for charging during the day. The device may be held closed by a strap that wraps around the device and loops back through the eyelets and then grabs itself via hook-and-loop fasteners (eg, manufactured by Velcro USA Inc., Manchester, NH). With the hook-and-loop fastener removed, the strap can be slid out of position around the lighting device (box 1204).

At box 1206, the light enclosure is opened by expanding it to form an open volume within the enclosure. Such action may involve simply releasing the device if the device is internally biased to the open position by an elastic cord tied between opposing ends within the housing, and the ends thereof are urged. The edges are furthest apart from each other when the housing is in its folded state and closest to each other when the housing is in its inflated state (as the cord pulls the housing into its inflated state by its natural shortening action). . Such opening can also involve first deploying the housing to its flattest configuration.

At box 1208, straps, which may be the same hook-and-loop straps that hold the device in its compressed and folded state, are secured to the edges of the housing. For example, the strap may be tied to an eyelet that is part of the housing, or may be pre-attached to the eyelet and retained there even when the device is folded and folded back. Often, the LEDs in the enclosure illuminate toward the floor of the room and into the room, and the bottom panel of the device is transparent so that the light generated within the enclosure can be easily illuminated downward into the room. It may be used to suspend the device from a ceiling or other elevated position so that it is distributed within.

In certain implementations, the tab to which the strap is most permanently attached may not be the best position for the light to be placed suspended to maximize the amount of downwardly shining light. can. In such situations, a second tab can be provided on the edge of the device, which is most naturally the top edge when the light is suspended from a high position, so that the user can easily see how the device is suspended from the strap. The strap can be slipped through such an opening in such a tab so that the last connection point of the strap to the body of the light should be the highest point (see Figures 2E and 2F). .

At box 1210, the lantern is activated. For example, a control panel, preferably in the form of one or more watertight buttons, can be provided around the device, and the user can press a button to turn on the lights, brighten or dim them. Other buttons may also be provided and their actuation may energize or de-energize an accessory plug on the device. In some implementations, the button may be pressed multiple times, with each press activating the lights of the device at different brightness levels, such as three brightness levels and an "off" level. Such different brightness levels can be achieved by illuminating the LEDs to different individual brightness levels, or by energizing a larger or smaller subset of all of the multiple LEDs in the device.

At box 1212, when the user has finished needing the light from the lantern, it can be lowered from where it was suspended, and the edges of the body of the lantern (at least the straps can be attached to the second attachment of the lantern, as in FIG. 2E). point)). The user can then initiate the process of folding the lantern into a smaller size for shipping (box 1214). A user can press two of the edges (e.g., hinge 106 in FIGS. 1A-1B) toward each other and/or push the scored side panels inward toward the center of the housing. You can do that by pressing The elastic cords can resist such housing compression, and the user can apply sufficient force to overcome that resistance until they completely flatten the housing (e.g., So essentially zero volume remains in the enclosure).

At this point, the device is flattened but not yet folded and is therefore relatively long (eg, double wide). As such, the device is long enough to accept a music player or smart phone on the side opposite the solar panel (box 1216). The user can squeeze the side of the device to open a sealable opening to the pouch on such side of the device and can place a finger in the opening to force it open, Electronic devices such as their smartphones can be slid inside. The user can similarly reach into the pouch to grasp the electrical plug inside the pouch and insert it into the smartphone's receptacle for such plug (box 1216). In some embodiments, the plug may be at the end of a short wire that can be manipulated by the user, or the user can self-manipulate through the plug without having to reach into the pouch to handle the plug. It may be fixed relative to the housing of the device so that the smart phone or other device can simply be slid. The user can then seal the pouch closed from water ingress in well known ways, such as by pressing a finger along the length of the seal to engage the elastic connecting channels together.

In certain embodiments, a smartphone or other device may also be operable when it is inside the pouch. For example, the lantern may have a physical data connection with a smartphone via a suitable plug, or it may have a wireless connection, such as via Bluetooth technology. The data connection can take the form of a lantern that passes data about its performance to applications running on the smartphone. For example, a lantern can show an application information about its current charge level, a schedule indicating when it has been charging and discharging, and other such operational information about the lantern. In another example, the lantern can pass information about the current energy level produced by the solar panel, allowing such information to be displayed in real time on the smartphone, allowing the user to control its charging. You can change the orientation of the lantern in real time with respect to the sun to maximize your level.

The smartphone and its running applications can also pass data to the lantern, such as information that controls the lighting of the lantern or other components of the lantern. For example, the user may run a sleep timer on the smartphone that turns on the lantern for a predetermined period of time and then can be turned off by the smartphone application sending a signal to the controller for the lantern device. In other examples, the smartphone sends a signal to change the color of the lighting produced by the lantern in a defined manner, such as in response to music playing from the smartphone or weather data collected from sensors or phones. can be sent.

The lantern can also be provided with one or more loudspeakers, the smart phone can provide music via the loudspeaker, and the loudspeaker and associated amplifier are in the lantern powered by the solar panel. Battery powered. In such situations, the smartphone and/or lantern will alert you when the battery is sufficiently depleted to leave a predetermined lighting period (e.g., only the two hours required for post-sunset meal prep and sleep prep). may be issued. A loudspeaker may also be integrated into one or more peripheral panels of the lantern, such as by being placed adjacent to the solar panel. In other embodiments, the loudspeaker may be constructed from a substantially transparent material and incorporated into the panel on the opposite side of the solar panel (if the enclosure is a six-sided box). A loudspeaker can be made waterproof by incorporating it into a semi-rigid insert that is molded to fit the speaker. This molded insert can then be sealed directly to one of the surfaces of the device, or multiple layers can hold it in place. In some variations, the solar panel circuit assembly can be on one side of the lantern and the loudspeaker can be on the other side. A wire can run from the speaker to the main circuit, further allowing the lantern to expand and collapse, the wire simply needs to be long enough to allow this.

At box 1218, the smart phone is being charged or otherwise in full use with the lantern and can be removed from the pouch. The user can then fold the lantern, such as by folding along the hinge between the two solar panels in the embodiment depicted above. The user tightens the straps around the folded lantern to completely flatten the lantern against the various layers of plastic panels pressed together and the elasticity of the various hinges stretched by compression and folding. , it can be attached to itself via hook-and-loop fasteners to hold it securely (box 1220). At this point, a pair of solar panels are facing outwards (e.g., FIG. 2A) and at least one is clipped to the outside of the user's backpack or otherwise attached to the outer surface of some structure and/or It can be pointed at the sun (even if the device is upside down), such as by lying or attached on top.

And in this way a multifunctional solar charging lantern can be equipped and used by the user. The lantern can be very flat and small for shipping, and can be slightly inflated to be placed in a sealed pouch to charge a portable electronic device, and emit light produced by one or more LEDs. It may be further expanded to provide lanterns that use that volume to better distribute within that volume.

In some situations, solar may not be a viable option for charging. For example, solar power is not so easily collected in areas where much of the sun is inaccessible, or during the winter months when the sun is far from the earth and cannot provide much power. In addition, in some situations, such as when a hurricane or storm is approaching and the device or backup battery needs to be recharged quickly, it is desirable to recharge quickly. In such situations, it is important that backup batteries and lanterns have multiple power inputs. It is also convenient to be able to connect or share power between products or between multiple power sources. For example, one backup battery can be used to charge other batteries by linking them via inputs and outputs.

The foldable solar lamp designs shown and described herein have multiple inputs and outputs so that they can be connected to each other and used to charge and power other devices. provide multiple methods of One advantage of providing input/output ports on the solar lantern is that users can use other power sources than the solar panel to charge the rechargeable battery. For example, if it is cloudy, the user can plug the device into a computer or wall outlet to recharge the battery. Additionally, users can use the rechargeable battery in the device as a backup battery when their phone is out of power and needs to be recharged. Another advantage of having ports is that multiple products can be linked together to share power, for example as shown in FIG. 11C, or additional The idea is that you can attach a solar panel to charge the lantern faster. This allows users more flexibility to create their own system specifications. If the user desires a product with a larger solar panel, the user can plug additional solar panels into the power input to recharge the product more quickly. If a user has two units, one with dead battery and one with full battery, the user can connect the unit with dead battery to the unit with full battery to share power. can be done.

In some variations of design, the foldable lamp can have both an integrated solar panel and a rechargeable battery. For example, a lamp can have an internal battery, but can be connected to an external solar panel during the day to charge it. In such cases, the user can connect the lamp to the solar panel during the day and charge it at the power input port, then remove it at night to carry the lantern indoors to provide light. Having input and output ports allows the user to personalize the system according to how and where they want to use it and what is convenient for charging and powering backup batteries and lanterns. ” can be created.

People often use bulky outdoor light bulbs connected together in long strings for outdoor lighting. Bulbs are often made of glass and are fragile and not easily transportable. However, they offer many advantages as they are bright and aesthetically pleasing. In some variations of this technology, a foldable light bulb can be designed and the PCB and LED can be integrated on one side of the light bulb. Silicon or other material can surround the electronic assembly to make it waterproof. The silicone or plastic cover can be arranged to fold towards and away from the LED depending on the amount of light required. It can also act as a lens to focus or spread the required amount of light. This independent light can have its own solar panel, or it can have an electrical cord that connects to another light bulb, flat pack battery, and solar panel.

The following paragraphs describe other specific embodiments and aspects of the inventions described herein. For example, in one embodiment, a solar powered lighting system is disclosed that includes a first device defining a peripheral shape and including a solar panel and a rechargeable battery; a second device defining a peripheral shape that matches and includes one or more LED lights; one or more physical connectors for securely attaching the first device to the second device; and one or more electrical connectors for forming a circuit such that power from the battery can be used to power the LED lights of the second device. A first device can include one or more LED lights that can be powered from a battery, and a second device powers one or more LED lights on the second device. It includes a separate battery and solar cell that can be used. Additionally, one or more physical connectors are integrated with one or more electrical connectors.

In some aspects, one or more physical connectors are magnetic locking connectors. The first device and the second device also have a third device in a row of physically connected devices capable of sharing with each other the electricity generated by the solar panel of at least one of the three devices. and can be daisy chained. Further, the first device and the second device can be configured to connect to each other at the origin of each device, each device having a housing that holds a respective LED light that radiates outward from the origin. . Additionally, a third device can be configured to have a housing that can be connected to the base point to hold the LED light and radiate outward from the base point.

In yet another aspect, the first device, the second device, or both are arranged to be wound within a closed tube. The closed tube can be provided with a plurality of LED lights near the first end of the tube to emit light in the form of a flashlight. A closed tube can also be formed from four or more flat sides that define a closed polygon of the tube. Further, the first device, the second device, or both can be configured to compress to a flat state. In some aspects, the first device may comprise a first apex of a star radiating from a base point, may include solar panels, and connect to the first device at the center point of the star. Additional devices may have LEDs powered from the power generated by the solar panels. The first device, one or more of the other devices, or both, to receive power from the first summit solar panel and later provide it for the operation of the other summit lighting. can include one or more rechargeable batteries of In some examples, a set of solar cells can be connected to multiple devices that have a common configuration, such as multiple peaks for a star. Each of the tops or other suitable devices can include batteries, LED lights, or both, the star or other system is charged from the solar panel, then after the device is disconnected from the solar panel, etc. can provide light to the Thus, in some examples, the solar panels discussed herein can be part of a lighting device, and in other examples, the solar panels used to power the device to which they are attached. At least some can be separate from their physically joined devices. Also, if there are multiple devices of a common form factor, some will fold more completely than others, for example, because some contain batteries or other somewhat bulky components and others do not. be able to.

In yet another embodiment, a flexible sheet substrate having a pair of two-dimensional surfaces and a plurality of electrical traces provided on at least one surface and configured to connect electrical devices on the at least one surface. a plurality of flexible solar cells disposed across one surface and electrically connectable to a battery; and a plurality of flexible solar cells physically connected to at least one surface and electrically connectable to the battery. A solar-powered lighting device with LED lights is disclosed. Both the LED lights and flexible solar cells can be on the same surface of the flexible sheet. Also, the LED lights and flexible solar cells can be on opposite surfaces of the flexible sheet. Further, the first surface can be divided into a grid of two-dimensional positions across the first surface, and flexible solar cells or LED lights can be placed at each intersection of the grid. Additionally, LED lights can be scattered across the surface using flexible solar cells.

In yet another embodiment, a solar powered lamp is disclosed comprising a plurality of concentric rings of decreasing diameter attached to each other in a pyramidal configuration. The upper edge of each ring is joined to the lower edge of each successively smaller ring to form a conical or pyramidal structure. To form a flat top plate, the structure may be cut away before reaching a predetermined point and the solar cells may be placed on the top plate. Rechargeable batteries and LED lights can also be placed on the flat top plate, with the LEDs pointing downwards to direct their light into the interior volume formed by each ring. The ramp can be folded into a flatter configuration with its top level pushed downward by each ring falling inside the next successive ring in the ramp. The point where the two rings meet can be scored or otherwise formed so that the rings fold in alternating directions to create a flatter structure. The flat top plate may be on the smallest or largest diameter portion of the device. A USB port or other form of data/power port may also be provided with the lamp so that the lamp can power an external load, or an external power source can power the lamp. (e.g. plugging a lamp into a USB cable that supplies electricity in one or both directions).

While this specification contains many specific implementation details, these are not intended as limitations on the scope of any invention or what may be claimed, but rather specific to particular implementations of particular inventions. should be construed as a description of the features. Certain features that are described in this specification in the context of separate implementations can also be implemented in combination in a single implementation. 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. Further, although features are described above and originally claimed as working in particular combinations, one or more features from the claimed combination may be separated from the combination where appropriate. and claimed combinations may cover subcombinations or variations of subcombinations.

Similarly, although operations have been drawn in the figures in a particular order, this does not mean that such operations are performed in the specific order or order shown, or that such operations are performed in order to achieve a desired result. It should not be understood to require that all actions taken are performed. Furthermore, the separation of various system components in the above-described embodiments should not be understood to require such separation in all embodiments, the components and systems described generally being a single product. It should be understood that it may be integrated into a product or may be packaged in multiple products. Also, several specific electrical systems are described (e.g., for powering the light, for charging devices external to the lamp, for charging the lamp from an external power source, etc.), and for several forms of lamps. Factors (eg, mechanical opening and closing cubes, stars, sheets, winding triangles for constructing tubes, etc.) are also described. In general, it should be understood that the electrical solutions described herein are equally applicable to each of the different physical lamp types (e.g., a USB port can be cubed or (can be protruding or parallel with other three dimensional extruded forms, or for flat sheet forms).

Thus, specific implementations of the subject matter have been described. Other implementations are within the scope of the following claims. In some cases, the actions recited in the claims can be performed in a different order and still achieve desirable results.

Claims (20)

A solar-powered lamp,
a plurality of radial extensions each radiating from a central axis of the lamp when the lamp is in an expanded state, each extension relative to one another along a line between each of the plurality of flat panels; a plurality of radial extensions formed from a plurality of collapsible flat panels;
A solar panel, a rechargeable battery, a printed circuit board, contained within a watertight enclosure and electrically interconnected, and arranged to direct light from inside the lamp through the flat panel of the plurality of radial extensions. an electronic assembly having one or more LEDs mounted thereon;
wherein the lamp is foldable and when the lamp is folded the flat panels of each of the radial extensions are folded against each other ;
The lamp can communicate the status of the lamp with a portable wireless device configured to control a plurality of lamps in coordination with each other, the lamp executing an application for control of the lamp. remotely controlled based on said communicated status by a type wireless device;
Solar powered lamp. each of the radial extensions comprises an apex that expands when the lamp is in an expanded state and flattens when the lamp is folded.
A solar-powered lamp according to claim 1. said lamp takes the shape of a star when in an expanded state;
3. The solar powered lamp of claim 2. the ramp is folded by rotating one or more of the apexes about the central axis and moving the apexes closer together;
3. The solar powered lamp of claim 2. a first peak comprising one or more solar panels and other peaks not comprising said solar panels;
3. The solar powered lamp of claim 2. the lamp includes a power port for charging electronics from the lamp's battery;
A solar-powered lamp according to claim 1. further comprising a removable cap that seals the power port in a water-tight manner;
7. Solar powered lamp according to claim 6 . the power port faces outward of the lamp along a line perpendicular to the plane of the printed circuit board;
7. Solar powered lamp according to claim 6 . the power port faces the outside of the lamp along a line parallel to the plane of the printed circuit board;
7. Solar powered lamp according to claim 6 . a first part attached to a first part of the lamp and a second part attached to a second part on the side of the lamp opposite to where the first part is attached and a handle having a
A solar-powered lamp according to claim 1. the lamp defines a sealed interior volume and is inflatable and deflatable;
A solar-powered lamp according to claim 1. further comprising a magnet configured to keep the lamp in an expanded state;
A solar-powered lamp according to claim 1. the lamp includes a plurality of charge indicator lights that illuminate a plurality of lights indicative of a current charge level of the battery in response to user input;
A solar-powered lamp according to claim 1. A solar-powered lamp for generating and providing electricity, comprising:
one or more solar panels;
one or more batteries configured to be charged by power from the one or more solar panels;
one or more light emitting devices (LEDs) configured to be powered by the one or more batteries;
one or more electrical connectors configured to receive power from the one or more batteries and connect to a combined power/data connection on a portable electronic device separate from the lamp;
said lamp status can be determined and said lamp status can be communicated to a portable wireless device configured to coordinately control a plurality of lamps with each other, said executing an application for control of said lamps; a microprocessor further capable of being remotely controlled based on said communicated status by the portable wireless device;
an inflatable and collapsible housing constructed from a plurality of pointed tapered elements;
The plurality of elements are
each radiating outward from a centerline of the device;
each having a plurality of flat walls,
foldable by rotating a portion of the housing about the centerline of the lamp;
positioned to receive light from the one or more LEDs and pass the received light through the plurality of flat walls;
Solar powered lamp. The lamp can be remotely controlled by a portable wireless device running an application for control of the solar powered lamp.
15. The solar powered lamp of Claim 14 . further comprising a removable cap that water-tightly seals the one or more electrical connectors;
15. The solar powered lamp of Claim 14 . the one or more electrical connectors face outward from the lamp along a line perpendicular to the plane of a printed circuit board connecting the one or more flat solar panels and the one or more batteries;
15. The solar powered lamp of Claim 14 . the one or more electrical connectors face outward from the lamp along a line parallel to the plane of a printed circuit board connecting the one or more flat solar panels and the one or more batteries;
15. The solar powered lamp of Claim 14 . the lamp defines a sealed interior volume and is inflatable and deflatable;
15. The solar powered lamp of Claim 14 . further comprising a magnet configured to keep the lamp in an expanded state;
15. The solar powered lamp of Claim 14 .

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