An inflatable solar-powered light is provided. The solar-powered light includes a bladder and a solar-powered light assembly disposed entirely within the bladder. The solar-powered light assembly includes a solar panel, a rechargeable battery in electrical communication with the solar panel, and at least one light-emitting diode in electrical communication with the rechargeable battery. The bladder is substantially transparent, flexible, inflatable, and collapsible.

Provided is an inflatable lamp, which includes a first flexible housing, a second flexible housing connected with the first flexible housing to cooperatively form a receiving cavity, a power supply assembly arranged on the first flexible housing, a light strip received in the receiving cavity, and a sealing assembly. The power supply assembly has a mounting element arranged on the first flexible housing and a power supply received in the mounting element. One end of the light strip is arranged on the mounting element and electrically connected with the power supply. The sealing assembly includes a first sealing element sealingly connected with an inner side of the first flexible housing. The first sealing element is configured to airtightly seal and cover the light strip, the mounting element, and the power supply. The inflatable lamp of the present disclosure is easy to carry and store.

Solar-powered lighting devices that may be portable and/or collapsible are described. The devices may include a housing including a first wall, a second wall, and one or more side walls between the first wall and the second wall, at least one solar panel to generate solar energy, and a rechargeable battery to store the solar energy generated. The devices may include a plurality of operating modes for controlling lights within the housing, and a microprocessor for controlling the operating modes.

Solar-powered lighting devices that may be portable and/or collapsible are described. The devices may include a housing including a first wall, a second wall, and one or more side walls between the first wall and the second wall, at least one solar panel to generate solar energy, and a rechargeable battery to store the solar energy generated. The devices may include a plurality of operating modes for controlling lights within the housing, and a microprocessor for controlling the operating modes.

An illumination device may include, but is not limited to: a shell portion; and a light projection device disposed at least partially within the shell portion, the light projection device including: at least one light source operably couplable to a power source; and at least one diffraction grating configured to distribute a light beam generated by the at least one light source onto an interior surface of the shell portion.

The present disclosure provides an apple-shaped light-emitting balloon. The apple-shaped light-emitting balloon includes a balloon body and a connecting rod. The connecting rod is positioned in the balloon body. The upper part and the lower part of the balloon body are fixed to the connecting rod respectively. An air inlet and an air outlet are formed in the connecting rod. A light-emitting part is further arranged in the balloon body. When the balloon is blown up, the connecting rod keeps a fixed distance between the upper part and the lower part of the balloon, so that the balloon is similarly apple-shaped, and the balloon is able to emit light.

The invention is an inflatable globe having a generally round shape and circumference of between 2 feet and 10 feet. An attachment pin, plug or other closure mechanism are coupled to the top of the inflatable globe. A topper is configured to fit over the attachment pin, plug or other closure mechanism. A hanger is threaded through the attachment pin, plug or closure mechanism and then through the topper. An electric light coupled to the plug is suspended inside the globe. The inflatable globe is made of a resilient polymer material and can be monochromatic or comprise a plurality of colors.

An adapting type of optical element in a shell-like accessory is disclosed. For a shell-like accessory formed by gluing fiber threads, an illuminating area is planned on the surface of shell-like accessory to develop lumen by combining laser elements to the illuminating area. The combination is implemented by adapting a transfer unit with a pitched fin to form a transient pinching. The transfer unit is implanted in advance in an implant area of the illuminating area. During implantation and combination, by the pinching and supporting of the pitched fins of the transfer units, angles of center lines of the transfer units can be adjusted, so that accurate projected angles of light beams from the post-adapted laser elements can be achieved.

The present disclosure provides a lighting device for use with inflatable products, such as balloons. Specifically, the lighting device may be configured to utilize external audio to produce a pattern of light corresponding with the external audio. The lighting device is able to couple to a balloon to light up the interior of the balloon without the significant loss of gas or other inflating fluid from the balloon.

In an aspect, an apparatus is provided and includes an air-tight object having an outer layer, an inner layer, and a cover, and a light module. The opacity of the outer layer is greater than the opacity of the inner layer. The outer layer defines a first aperture and a second aperture. The inner layer and the cover define a first interior region. The inner layer defines a second interior region. The light module is encapsulated within the first interior region and is configured to send light through the inner layer, through the second interior region of the air-tight object, and through the second aperture of the outer layer, wherein the cover is disposed between the light module and the outer layer.