A light tower includes a base, an extendible mast coupled to the base, a battery pack supported on the base and including a plurality of lithium-ion battery cells, a light assembly including a plurality of light emitting diodes electrically coupled to the battery pack, a display configured to receive inputs and display information, and a controller in communication with the battery pack, the light assembly, and the display. The configured being to: receive a light intensity change input from the display, change a power provided by the battery pack to the light emitting diodes in response to the light intensity change input, and display on the display a change in runtime resulting from the change of the power provided by the battery pack to the light emitting diodes.

A light tower includes a generator assembly including a prime mover, an alternator operably connected to the prime mover, the alternator configured to produce alternating current electrical energy, and a rectifier operably connected to the alternator and configured to convert alternating current electrical energy produced by the alternator to direct current electrical energy. At least one light emitting diode matrix is electrically connected to the generator assembly by an electrical connection, and a regulator is operably connected to the alternator and configured to detect a current of the direct current electrical energy in the electrical connection. In response to a detected current of the direct current electrical energy in the electrical connection, the regulator controls the alternator to adjust the current supplied to the at least one light emitting diode matrix.

A light tower includes a generator assembly including a prime mover, an alternator operably connected to the prime mover, the alternator configured to produce alternating current electrical energy, and a rectifier operably connected to the alternator and configured to convert alternating current electrical energy produced by the alternator to direct current electrical energy. At least one light emitting diode matrix is electrically connected to the generator assembly by an electrical connection, and a regulator is operably connected to the alternator and configured to detect a current of the direct current electrical energy in the electrical connection. In response to a detected current of the direct current electrical energy in the electrical connection, the regulator controls the alternator to adjust the current supplied to the at least one light emitting diode matrix.

Provided are wearable lights or lights that can be attached to accessories when carrying out activities in low-light or no-light conditions. The wearable lights incorporate a portion of non-magnetic material with an internal chamber with a low friction internal surface that is surrounded by a copper coil. A magnet is passed through the internal chamber, allowing the copper coil to break the magnetic fields of the magnet, which creates a burst of electrical current. The current is used to emit light through LED's. Movement of the wearer/user generates the movement of the magnet in the internal chamber, and repelling magnets at the top and bottom of the internal chamber assist the magnet in moving back and forth through the chamber. The inventive device can be adapted for use in many sporting and other applications, such as in running shoes, running belts, rucksacks and as stand-alone wearable lights.

Provided are wearable lights or lights that can be attached to accessories when carrying out activities in low-light or no-light conditions. The wearable lights incorporate a portion of non-magnetic material with an internal chamber with a low friction internal surface that is surrounded by a copper coil. A magnet is passed through the internal chamber, allowing the copper coil to break the magnetic fields of the magnet, which creates a burst of electrical current. The current is used to emit light through LED's. Movement of the wearer/user generates the movement of the magnet in the internal chamber, and repelling magnets at the top and bottom of the internal chamber assist the magnet in moving back and forth through the chamber. The inventive device can be adapted for use in many sporting and other applications, such as in running shoes, running belts, rucksacks and as stand-alone wearable lights.

Disclosed is a compact portable light tower that can be stacked or nested. The light tower employs a scissors lift mechanism to raise a set of bar lights from a housing having a height of about 28 and a length of about 60, to an extended height of about 360. The scissors lift is extended and retracted by use of a linear actuator. Batteries or an engine/generator assembly is employed for operation of the actuator and light bar. The housing can be stacked for ease of storage and transportation. Outriggers provide stabilization of ground engagement.

An illuminated glove assembly includes a glove and an illumination data controller. The glove has a body portion, a longitudinal glove axis, a pointer extension, a pinky extension, a wrist strap and a pocket portion. The wrist strap is positioned at a proximal end of the body portion. A securing mechanism is connected to the wrist strap and the pointer extension and pinky extension extend from a distal end of the body portion. The pointer extension is positioned on a first side of the longitudinal axis and the pinky extension is positioned on a second side of the longitudinal axis. The pocket portion is secured to and defines a pocket with the body portion. An opening of the pocket is defined proximate the distal end of the body. The illumination data controller is configured for selective mounting in the pocket and includes a housing with a front face.

An apparatus and method are provided for converting broad spectrum electromagnetic energy to useful, narrow bands of electromagnetic energy. The broad spectrum electromagnetic energy may be from the Sun or from combustion, and output from the apparatus may be bands of visible light, infrared, microwaves, or a combination thereof. The apparatus can function as part of a highly efficient plant growing system or may function as part of a heating or warming system.

A hybrid light tower includes an engine, a generator configured to be driven by the engine, a battery pack, a mast, and a light assembly including a plurality of light emitting diodes. The generator is configured to produce a first DC power. The battery pack is directly electrically coupled to the generator to receive the first DC power from the generator to charge the battery pack. The light assembly is coupled to the mast and the light emitting diodes electrically coupled to the battery pack to receive a second DC power from the battery pack.

A flashlight is provided. The flashlight includes a frame defined by a rail that extends around a central opening predominantly within a single plane, a mounting loop extending outboard of the frame on a first end, a planar circuit board disposed within the central opening. The plane of the circuit board coincident with the plane of the frame, an LED light disposed on the circuit board, where a light emitting end of the LED light extending through the frame on a second end of the frame opposite the first end. A rechargeable battery is disposed on the circuit board, a switch is provided that couples the battery to the LED light. An actuator of the switch extends through the frame between the first and second ends, a USB connector is disposed on the circuit board, the USB connector extends through the frame between the first and second ends and a battery charger is disposed on the circuit board that charges the battery via energy received through the USB connector.