A solar collection system is mounted inside a containment vessel. The upper portion of the containment vessel is optically transparent and includes one or more lens elements to help direct light to an upward facing solar panel. The lower portion of the containment vessel comprises a mirrored surface to help reflect light upward to a downward facing solar panel. The shape of the upper and lower portions of the containment vessel may be altered based on the selected implementation. A variety of lens configurations may also be used.

Devices configured to direct heat flow are disclosed, as well as methods of forming thereof. A device may include a self-assembling heat flow object. The self-assembling heat flow object may include a material having one or more self-assembling properties that cause the material to react to an environmental stimulus and one or more thermal pathways. An application of the environmental stimulus causes the self-assembling heat flow object to deploy and arrange the one or more thermal pathways for directing thermal energy to one or more locations.

Devices configured to direct heat flow are disclosed, as well as methods of forming thereof. A device may include a self-assembling heat flow object. The self-assembling heat flow object may include a material having one or more self-assembling properties that cause the material to react to an environmental stimulus and one or more thermal pathways. An application of the environmental stimulus causes the self-assembling heat flow object to deploy and arrange the one or more thermal pathways for directing thermal energy to one or more locations.

An apparatus for predicting useful life of a photovoltaic module includes an input and an output. The input receives first information indicating an amount of hygrothermal stress that a photovoltaic module undergoes from a start until an end of a period during which the photovoltaic module outputs predetermined electric power. The input further receives second information indicating an amount of hygrothermal stress that the photovoltaic module undergoes per a predetermined time in a field where the photovoltaic module is deployed. The second information is generated based on information about daily maximum temperatures of the photovoltaic module in the field where the photovoltaic module is deployed. The output outputs result information about a predicted period during which the photovoltaic module is expected to output the predetermined electric power when the photovoltaic module is deployed in the field.

An apparatus for predicting useful life of a photovoltaic module includes an input and an output. The input receives first information indicating an amount of hygrothermal stress that a photovoltaic module undergoes from a start until an end of a period during which the photovoltaic module outputs predetermined electric power. The input further receives second information indicating an amount of hygrothermal stress that the photovoltaic module undergoes per a predetermined time in a field where the photovoltaic module is deployed. The second information is generated based on information about daily maximum temperatures of the photovoltaic module in the field where the photovoltaic module is deployed. The output outputs result information about a predicted period during which the photovoltaic module is expected to output the predetermined electric power when the photovoltaic module is deployed in the field.

A solar panel module including a cover, a back plate, at least two solar panels, and at least a dark insulating layer is provided. The solar panels are configured between the cover and the back plate and arranged along a direction. There is a separating gap of a width arranged between the two adjacent solar panels. In addition, the dark insulating layer is disposed in the separating gap.

Devices configured to direct heat flow are disclosed, as well as methods of forming thereof. A device may include a self-assembling heat flow object. The self-assembling heat flow object may include a material having one or more self-assembling properties that cause the material to react to an environmental stimulus and one or more thermal pathways. An application of the environmental stimulus causes the self-assembling heat flow object to deploy and arrange the one or more thermal pathways for directing thermal energy to one or more locations.

Devices configured to direct heat flow are disclosed, as well as methods of forming thereof. A device may include a self-assembling heat flow object. The self-assembling heat flow object may include a material having one or more self-assembling properties that cause the material to react to an environmental stimulus and one or more thermal pathways. An application of the environmental stimulus causes the self-assembling heat flow object to deploy and arrange the one or more thermal pathways for directing thermal energy to one or more locations.

A roadway subsurface sensor system includes roadway housings arranged to define a surface to carry vehicles. Each roadway housing has a sensor assembly having a housing, and sensor layers received by the housing. Each roadway housing also has a drainage layer under the sensor assembly. An uppermost sensor layer from the sensor layers is to provide the surface to carry vehicles. The roadway subsurface sensor system further includes a management controller coupled to the sensor layers. The management controller is configured to process sensed data from the sensor layers.

Method and apparatus for annealing micro-scale or macro solar cells that can contain lithium. Heaters, a current that is applied in forward or reverse direction, or open-circuiting the cells are used optionally with a laser or other light source to increase the temperature of the cells to perform periodic anneals to recover energy conversion efficiency lost due to environmental conditions such as radiation damage and maintain desired operational conditions. While a small amount of energy is used for heating up the small thermal mass of the micro-cells and macro cells to the desired annealing temperature, much larger amounts of additional energy is harvested with the improved efficiency of the cells. Maintaining a desired temperature for operation of cells takes very little energy owing to the small thermal mass of the cells and controlled thermal conduction of the materials in contact with the cells.