A system for mounting a service component to a building structure has a plurality of elongate feet, and a plurality of connectors that each interconnect a respective one of the feet with the service component. Each foot is configured to affix to a surface of the building structure and then to resist disengagement from that surface. The connectors each interconnect a respective one of the feet with the service component, and secure the relative position of the respective foot and the service component. An elongate beam can be connected or connectable to the service component, such that in the installed system the beam is to be positioned to extend obliquely across the feet.

A deployable solar photovoltaic power generation system includes an array of photo voltaic panels mounted to expandable truss. In response to environmental input data, the array of photovoltaic panels can be deployed or stowed.

In accordance with exemplary inventive practice, a catalytic system and a temperature swing adsorption system are thermally integrated. The temperature range of the adsorption system is lower than the catalyst operating temperature. Benefits of inventive practice include reduction of total energy consumption and of generated waste-heat. Total energy consumption is reduced by transferring some of the waste-heat generated by the catalytic system into the adsorption system during the sorbent heat-up portion of the sorbent regeneration cycle. The heat is transferred using a thermal reservoir, which accumulates heat from the catalytic apparatus and transfers it to the adsorption apparatus at a later time, and which is repeatedly cycled as the sorbent is cycled. The catalytic system and the adsorption system can be inventively integrated in various ways to reduce the total energy consumed, and/or to modify the sorbent regeneration temperature profile, and/or to obtain an optimum power load profile.

In accordance with exemplary inventive practice, a catalytic system and a temperature swing adsorption system are thermally integrated. The temperature range of the adsorption system is lower than the catalyst operating temperature. Benefits of inventive practice include reduction of total energy consumption and of generated waste-heat. Total energy consumption is reduced by transferring some of the waste-heat generated by the catalytic system into the adsorption system during the sorbent heat-up portion of the sorbent regeneration cycle. The heat is transferred using a thermal reservoir, which accumulates heat from the catalytic apparatus and transfers it to the adsorption apparatus at a later time, and which is repeatedly cycled as the sorbent is cycled. The catalytic system and the adsorption system can be inventively integrated in various ways to reduce the total energy consumed, and/or to modify the sorbent regeneration temperature profile, and/or to obtain an optimum power load profile.

A swivel and fanning drive for solar panels, including a base support, a swivel plate mounted pivotingly about a horizontal axis, and a plurality of solar panels that can be fanned in and out about a fan-out axis. The swivel plate can be pivoted by at least one crank and connecting rod. Pivotal movement of the swivel plate about a vertical axis can cause the solar panels to be fanned-in or fanned-out. A brake can resist movement of the solar panels about the fan-out axis.

A swivel and fanning drive for solar panels, including a base support, a swivel plate mounted pivotingly about a horizontal axis, and a plurality of solar panels that can be fanned in and out about a fan-out axis. The swivel plate can be pivoted by at least one crank and connecting rod. Pivotal movement of the swivel plate about a vertical axis can cause the solar panels to be fanned-in or fanned-out. A brake can resist movement of the solar panels about the fan-out axis.

A portable solar power system is disclosed. The system includes a wheeled support and transport platform with a center mast. Secured to the mast is a panel system comprising at least two solar panels, which may be folded into a stable and aerodynamic upwardly extending position for transportation. The mast, by means of at least one slewing drive, allows for rotation and positioning of the solar panels for maximum sun exposure.

A portable solar power system is disclosed. The system includes a wheeled support and transport platform with a center mast. Secured to the mast is a panel system comprising at least two solar panels, which may be folded into a stable and aerodynamic upwardly extending position for transportation. The mast, by means of at least one slewing drive, allows for rotation and positioning of the solar panels for maximum sun exposure.

A plate folding and unfolding device and a solar panel structure are provided. The plate folding and unfolding device includes a cam fixed with first plate piece, and a rotating shaft is disposed inside the cam in an axial direction of the cam; a connecting rod, where the connecting rod includes a first end and a second end that are opposite to each other, the first end is connected vertically to the rotating shaft, and the second end is fixed to a second plate piece; a positioning shaft, where the positioning shaft is disposed, on the connecting rod; and an elastic piece, where the elastic piece is disposed on the connecting rod, one end of the elastic piece is connected to the positioning shaft, where a groove that accommodates the positioning shaft is disposed at at least one location of the outer peripheral surface of the cam.

Embodiments disclosed herein are directed to a rapidly deploying transportable power system for generating power. The rapidly deploying transportable power system embodiment disclosed herein can have a plurality of frame members containing a plurality of solar panels. Any embodiments of the rapidly deploying transportable power system can also have a transport enclosure configured to support the plurality of frame members and a rail system coupleable with the transport enclosure, the rail system being configured to support the plurality of frame members outside of the transport enclosure. In any embodiments, the plurality of frame members can be positionable within the transport enclosure with one frame member positionable above another frame member. Furthermore, the plurality of frame members can be movable along the rail system to positions outside of the transport enclosure along the track system.