A thermal management system (TMS) for controlling the temperature of a selective reflective panel is disclosed. The TMS includes a solar concentrator array, a temperature sensor, and a controller. The solar concentrator array is located within the selective reflective panel and has a plurality of reflectors arranged in reflector groups. The temperature sensor monitors a temperature of the selective reflective panel at a location of the temperature sensor. The controller monitors the local temperature of the selective reflective panel utilizing the temperature sensor and, in response, produces a control signal that is sent to the solar concentrator array. The control signal directs the solar concentrator array to position a selected number of reflectors on the concentrator array into an off-pointing position in response to monitoring the temperature sensor, where the selected number of reflectors is determined to control the local temperature of the selective reflective panel.

A thermal management system (TMS) for controlling the temperature of a selective reflective panel is disclosed. The TMS includes a solar concentrator array, a temperature sensor, and a controller. The solar concentrator array is located within the selective reflective panel and has a plurality of reflectors arranged in reflector groups. The temperature sensor monitors a temperature of the selective reflective panel at a location of the temperature sensor. The controller monitors the local temperature of the selective reflective panel utilizing the temperature sensor and, in response, produces a control signal that is sent to the solar concentrator array. The control signal directs the solar concentrator array to position a selected number of reflectors on the concentrator array into an off-pointing position in response to monitoring the temperature sensor, where the selected number of reflectors is determined to control the local temperature of the selective reflective panel.

A solar actuator comprises a top coupler, a bottom coupler, and a plurality of fluidic bellows actuators, wherein a fluidic bellows actuator of the plurality of fluidic bellows actuators moves the top coupler relative to the bottom coupler.

A solar actuator comprises a top coupler, a bottom coupler, and a plurality of fluidic bellows actuators, wherein a fluidic bellows actuator of the plurality of fluidic bellows actuators moves the top coupler relative to the bottom coupler.

A series of photovoltaic panels (PV) arranged on a planar, horizontal support platform so as to form a PV array that is pivotally connected to a PV array support structure that can pivotally raise, angle and support the PV array above agricultural fields at heights that allow the passage of large mechanized farm equipment to pass beneath. The PV array support structure pivotally raises its PV array into its operating elevation and positional range with a system of motorized pivot arms operationally positioned between its array columns and the members of the support frame. Once in place, these PV arrays may be horizontally moved by tilting or angling the array columns within a specified operating range (by computer positioning known as dynamic shifting). At the same time, the PV panels may all be optimally tilted for sun sharing and sun shading for both the generation of electricity and to increase the agricultural efficiency of the underlying land.

A robotic actuator comprises a mass manufactured bellows, wherein the mass manufactured bellows allows a volume change by localized bending, and wherein the mass manufactured bellows is formed from a material that has a higher strength in at least two axes relative to at most one other axis, and an end effector, wherein the end effector is coupled to the manufactured bellows.

A robotic actuator comprises a mass manufactured bellows, wherein the mass manufactured bellows allows a volume change by localized bending, and wherein the mass manufactured bellows is formed from a material that has a higher strength in at least two axes relative to at most one other axis, and an end effector, wherein the end effector is coupled to the manufactured bellows.

A solar tracking system preferably associated with a double-reflecting dish solar concentrator having an initial parabolic reflective surface for concentrating solar energy upon a focal cloud preferably spatially coinciding with the primary focus of a subsequent elliptical reflective surface for further concentrating solar energy within a beam directed through an opening defined, preferably at the origin, by the initial parabolic reflective surface to heat a thermal transfer fluid flowing through a heating element; said subsequent elliptical reflective surface having a photovoltaic element on its reverse; said photovoltaic element being divided into plural sections, preferably quadrants, from which respective photovoltaic-based voltmeter readings are utilized to reposition the initial parabolic reflective surface's axis of symmetry closer to parallel with the plurality of incoming solar energy thereby effectively tracking the sun and maximizing collectable/concentrated solar energy.

A fluidic solar actuation array, the fluidic solar actuation array comprising a plurality of separate actuator nodes disposed in a node line. The node line comprises a set of two or more actuator nodes and a pressure supply line that fluidically couples the set of two or more actuator nodes, with each of the two or more actuator nodes comprising a fluidic solar actuator that includes at least a first fluidic inflatable actuator.

The present invention relates to a system for the production of carbon nanotubes from carbonaceous matter, preferably, plastic waste and solar energy; Method of production.