An arc detection and intervention system for a solar energy system. One or more arc detectors are strategically located among strings of solar panels. In conjunction with local management units (LMUs), arcs can be isolated and affected panels disconnected from the solar energy system.

A dialysis system (e.g., a hemodialysis (HD) system) can be designed to operate in alternative environments, such as disaster relief settings or underdeveloped regions. The dialysis system can include a solar panel for generating electricity to power the dialysis machine and an atmospheric water generator for extracting water from ambient air. The extracted water can be used to generate dialysate and saline on-site. One or more of the components of the dialysis machine can be discrete components that are configured to facilitate fast shipping and simple on-site assembly (e.g., at a remote location). In some implementations, the discrete components may be configured to be attached to an existing dialysis system (e.g., a dialysis system designed for operation in a traditional environment) to permit the dialysis system to operate in an alternative environment.

A dialysis system (e.g., a hemodialysis (HD) system) can be designed to operate in alternative environments, such as disaster relief settings or underdeveloped regions. The dialysis system can include a solar panel for generating electricity to power the dialysis machine and an atmospheric water generator for extracting water from ambient air. The extracted water can be used to generate dialysate and saline on-site. One or more of the components of the dialysis machine can be discrete components that are configured to facilitate fast shipping and simple on-site assembly (e.g., at a remote location). In some implementations, the discrete components may be configured to be attached to an existing dialysis system (e.g., a dialysis system designed for operation in a traditional environment) to permit the dialysis system to operate in an alternative environment.

An ultrastable cementitious material with nano-molecular veneer makes a cementitious material by blending 29 wt % to 40 wt % of a magnesium oxide dry powder containing 80 wt % to 98 wt % of magnesium oxide based on a final total weight of the cementitious material, with 14 wt % to 18 wt % of a magnesium chloride dissolved in water and reacting to form a liquid suspension, mixing from 2 to 10 minutes, adding a phosphorus-containing material, and allowing the liquid suspension to react into an amorphous phase cementitious material, wherein a portion of the amorphous phase cementitious material grows a plurality of crystals. The plurality of crystals are encapsulated by the amorphous phase cementitious material forming a nano-molecular veneer. A process to make the ultrastable cementitious material. A tile backer board incorporating the ultrastable cementitious material and a process for making the tile backer board.

An ultrastable cementitious material with nano-molecular veneer makes a cementitious material by blending 29 wt % to 40 wt % of a magnesium oxide dry powder containing 80 wt % to 98 wt % of magnesium oxide based on a final total weight of the cementitious material, with 14 wt % to 18 wt % of a magnesium chloride dissolved in water and reacting to form a liquid suspension, mixing from 2 to 10 minutes, adding a phosphorus-containing material, and allowing the liquid suspension to react into an amorphous phase cementitious material, wherein a portion of the amorphous phase cementitious material grows a plurality of crystals. The plurality of crystals are encapsulated by the amorphous phase cementitious material forming a nano-molecular veneer. A process to make the ultrastable cementitious material. A tile backer board incorporating the ultrastable cementitious material and a process for making the tile backer board.

Embodiments related to a power platform having a mobile trailer, a tower pivotally attached to the mobile trailer, and a plurality of power sources. The plurality of power sources including at least a solar panel disposed on the tower and a fuel cell generator. The power platform also includes a housing having a transfer switching assembly and a power cord panel, wherein the transfer switching assembly is configured to receive electrical power generated from the plurality of power sources and convert the electrical power for transfer to ancillary devices via the power cord panel.

Embodiments related to a power platform having a mobile trailer, a tower pivotally attached to the mobile trailer, and a plurality of power sources. The plurality of power sources including at least a solar panel disposed on the tower and a fuel cell generator. The power platform also includes a housing having a transfer switching assembly and a power cord panel, wherein the transfer switching assembly is configured to receive electrical power generated from the plurality of power sources and convert the electrical power for transfer to ancillary devices via the power cord panel.

A thermoelectric power generation system includes a solar panel array on a first side of a tower to absorb solar radiation and generate electrical energy and waste heat and a panel on a second side, opposite the first side, of the tower. A plurality of thermoelectric elements of the tower are interposed between the solar panel array and the panel. The plurality of thermoelectric elements converts conductive heat flow of the waste heat from the solar panel directed toward the panel to electrical energy. A conductive base supports the tower and to conduct heat away from the panel.

A hybrid solar thermal and photovoltaic power generation system with a pumped thermal storage system with a mode switchable heat pump/heat engine apparatus realizes utility scale stabilized power generation with low cost thermal storage, ultra-high conversion efficiency with hybrid solar thermal and photovoltaic cogeneration system, and low capital cost with the mode switchable heat pump/heat engine apparatus. The present system heat, cool, and supply power to buildings simultaneously over the four seasons. The synergistically combination of the hybrid solar thermal and photovoltaic cogeneration and the pumped thermal storage of the present invention is to make a transformative change of power supply landscape.

A hybrid solar thermal and photovoltaic power generation system with a pumped thermal storage system with a mode switchable heat pump/heat engine apparatus realizes utility scale stabilized power generation with low cost thermal storage, ultra-high conversion efficiency with hybrid solar thermal and photovoltaic cogeneration system, and low capital cost with the mode switchable heat pump/heat engine apparatus. The present system heat, cool, and supply power to buildings simultaneously over the four seasons. The synergistically combination of the hybrid solar thermal and photovoltaic cogeneration and the pumped thermal storage of the present invention is to make a transformative change of power supply landscape.