A mobile solar generator for autonomous and continuous supply of electricity in a transportable automatically or semi-automatically unfolding/folding system. The mobile solar generator generally includes photovoltaic modules, energy storage (lithium ion batteries), power converters, and a mechanical system to fold/unfold the photovoltaic modules. The mobile solar generator may also optionally include a detachable trailer. The mobile solar generator typically has the ability to provide alternating current at a voltage of 120 or 230V single-phase or three-phase 400 V/460V 50 or 60 HZ. Electricity is generally provided by 12, 16 or 24 photovoltaic modules 347 W depending on the version of the product is typically a photovoltaic power 4, 5, or 8 KWp. The mobile solar generator can preferably be folded on itself for shipping purposes. The SMG can also include skids for water treatment or other skids which use the power generated by the SMG.

A low cost thin-film based heliostat with advanced stowing and wind survival capabilities. The heliostat may include a plurality of reflective surfaces held together via a plurality of double acting magnetic hinges. The heliostat may also include a drive mechanism attached to a post, and configured to stow the plurality of facets in any desired position.

The present application describes an automated structure for reception of modular constructions and respective automation system comprised by a lower structure (1), which contains an opening (4) for accommodation of a fixed shaft, comprised by the element of attachment of the shaft with the exterior, where, preferably, the structure and the fixed shaft of fixation to the exterior (5) can be coupled, a lifting mechanism (2) preferably located in the side sections of said lower structure (1) which is coupled to an upper structure (3) allowing its movement through the joint and support (6). The axial movement and the upper structure (3) are managed through an automated system based on a programmable automaton and a set of sensors and actuators, namely anemometers and frequency inverters that control these movements. This way, the present invention makes it possible to receive modular constructions, for example houses, making them move, for example, according to the solar orientation, in order to make them energy efficient.

A heat exchange device including a flexible hinge, a solar collector, a tank containing serpentine or coiled tubes which contain municipal water, wherein the tank contains thermal transmission vents designed for outflow of hot gasses from an attic, an insect screen, a precipitation drain and an attachment area is hereby disclosed.

Broadband reflectors include a UV-reflective multilayer optical film and a VIS/IR-reflective layer. In various embodiments, the VIS/IR reflective layer may be a reflective metal layer or a multilayer optical film. Concentrated solar power systems and methods of harnessing solar energy using the broadband reflectors and optionally comprising a celestial tracking mechanism are also disclosed.

An assembly for positioning photovoltaic panels on a structure includes a main frame connectable to the structure, and a subassembly connectable to the main frame to support a photovoltaic panel, in which the subassembly is rotatable with respect to the main frame to place the subassembly in a deployed position. The assembly may further include a stop-arm connectable to the main frame to support the subassembly when in the deployed position.

An integrated preassembled solar panel module includes a solar panel configured for receiving and converting solar radiation to produce electrical power. Multiple mounting feet are coupled to the solar panel at selected locations. One or more sheathing anchors are configured for coupling the mounting feet to roof sheathing at locations not overlapping roof rafters and thereby securing the solar panel to the roof sheathing without accessing an underside of the roof sheathing.

A system of solar PV strip modules and method of use designed to integrate with vertical structures such as poles. The system and method use articulated semi-rigid solar PV strip modules and components with elastic characteristics to enable a high static-friction attachment to the structure. The static friction exceeds the force of gravity, enabling the solar PV strip modules to remain in place upon the vertical structure. The PV strip modules can have a rectangular shape or any other shape that enables customized or variable modular assembly and attachment to the structure.

A solar-powered system includes a mounting assembly to affix a solar active component mounted to a support member by the mounting assembly, such that both sides of the solar active component have solar exposure.

A drone landing system includes a solar collector to charge the drone at a landing cite of the drone landing system. The solar collector may include a solar collector mounting assembly, preferably comprises a bi-facial solar active component mounted with its solar active face(s) orthogonal to the ground/horizon, at or near its perimeter frame.