Abstract: In a solar receiver arrangement 300 with a support structure 600, the support structure 600 includes a plurality of tie members 700 for tangentially coupling a plurality of tubes 510, for forming at least one receiver panel 500, in such a manner that the at least one tie member 700 is coupled in at least one crotch portion 520 between a pair of tubes 510. The support structure 600 further includes a plurality of panel support members 800 coupled to the receiver panel 500 selectively in at least one crotch portion 520 between a pair of tubes 510. Furthermore, at least one latching member 900 is configured to detachably attach the plurality of panel support members 800 for engaging the plurality of receiver panels 500.

Abstract: A heat receiver tube having first, second, and further partial heat receiver tube surfaces for absorbing and transferring solar energy to heat transfer fluid is presented. The first and further partial heat receiver tube surfaces are formed by solar absorptive coatings deposited on partial surfaces of core tube. The second partial heat receiver tube surface is formed by emission radiation inhibiting coating deposited on second core tube surface for inhibiting emissivity for infrared radiation. The further partial heat receiver tube surface is arranged in radiation window of second partial heat receiver tube surface such that direct sunlight impinges further partial heat receiver tube surface. The heat receiver tube is arranged in focal line of parabolic mirror of parabolic trough collector. The first partial heat receiver tube surface and sunlight reflecting surface is arranged face to face, second and further partial heat receiver tube surfaces are averted to reflecting surface.

Abstract: Embodiments disclosed provide a sunshade apparatus that integrates a solar collector into an attractive architectural sunshade, and a system for deriving energy, and in particular heat, from such an apparatus. The sunshade is comprised of between one and several solar collector panels. Each panel has an infrared clear pass face and contains tubing. The panel may also contain a layer of insulation underneath the tubing. The tubing contains a fluid and is connected to a solar water system. The clear face extends for most but not all of the upper surface of the panel, such that the ends are solid to provide structural support for the panel. The panels are designed in advance for use in connection with an architectural feature, such as a window on a building, with angles for each of the panels and in some cases the shade as well. Aesthetic architectural options including interior beam colors and clear face coatings are contemplated.

Abstract: The present application relates to a vacuum solar thermal panel (1) of the type comprising: a vacuum- tight envelope (10), having at least a front plate (11) transparent to solar radiation and a support structure (12) for said front plate (11); heat-absorbing means enclosed within said vacuum-tight envelope (10); and main getter means for keeping a vacuum condition within the vacuum envelope (10); wherein the vacuum solar thermal panel (1) further comprises a pressure indicator spot (13) of reactive material deposited on an inner side of said front plate (11), said reactive material undergoing a reaction noticeable from the outside of the vacuum-tight envelope (11) when the pressure within said envelope exceeds a given threshold.

Abstract: In various representative aspects, an assembly for supporting and penetrating metallic solar panel frames to provide a grounding path between the panels, holding ballast of various masses to stabilize the solar panels, and allowing the solar panels to tilt to an adjustable angle is disclosed herein. The assembly has a support member with a pair of vertical components, a ballast holder and a mounting member with at least a raised portion to penetrate a surface of a solar panel and form a grounding path between the assembly and the solar panel. The mass of ballast is adjustable by placing various number of ballast blocks in the ballast holder to stabilize the attached solar panel. The mounting member is pivotally coupled to at least one of the vertical components of the support member so that the angle between the solar panel and the assembly may be adjusted.

Abstract: Systems, methods, and apparatus by which solar energy is efficiently collected to provide heat, electricity, or a combination of heat and electricity include a solar energy collector having a receiver, a first reflector and a second reflector arranged end-to-end such that an edge of the first reflector overlaps an edge of the second receiver; and a support structure that accommodates movement of the receiver, rotation of the reflectors, or rotation of the receiver and the reflectors about an axis parallel to a long axis of the receiver. The support structure has reflector supports oriented transverse to the rotation axis and reflectors are securable to the reflector support.

Abstract: A solar panel cap and light cap secured to a wall or parapet through the use of a fixed coping having two vertical supports on either side of a locking channel. The vertical supports are biased or resilient to secure the coping to the top of the parapet or wall. The locking channel is configured to slidably receive a locking insert from a solar panel cap or light cap, each configured to connect to an adjacent cap such that they are electrically coupled. The solar panel caps include a horizontal base and an angled solar panel pivotally attached on one edge to the horizontal base. Support plates are pivotally attached to opposite edges of both the horizontal base and the angled solar panel such that when they overlap and are secured to one another the angled solar panel is adjustably positionable relative to the horizontal base.

Abstract: A solar panel mounting system may include a solar panel mounting assembly for mounting to a support structure. The solar panel mounting assembly may include a restraining element, a retaining element and a biasing assembly that supports the restraining and retaining elements. The support structure may include an upper surface and a lower surface spaced from the upper surface. The biasing assembly may further include a biasing element that resiliently urges the retaining element toward a securing element for supporting a solar panel that is positioned between the retaining element and the upper surface of the support structure, and resiliently urges the restraining element toward the lower surface of the support structure. A retention device may resiliently bias the solar panels of a solar panel assembly together on a support structure.

Abstract: A solar radiation absorber element for a thermal concentrating solar power plant is achieved by forming a selective coating on an outer surface of a substrate made from stainless steel, chosen from stainless steels presenting an aluminium content of more than 0.5% by weight. Formation of the selective coating includes a surface treatment step of the substrate, by polishing, and a heat treatment step of the substrate, in an oxidizing atmosphere, in a temperature range included between 550° C. and 650° C. The heat treatment in particular enables at least one intrinsically selective superficial thin layer to be formed on the outer surface of the substrate.

Abstract: A sun tracking solar power generation system can include drive members for driving a plurality of parallel sun tracking assemblies. The drive components of the drive system can be arranged in a recess or trench created in the ground. This arrangement can reduce the material and labor costs for constructing a solar power system.

Abstract: A sun tracking solar energy collection system can include torque tubes formed with a plurality of rotatable shafts connected to each other in an end to end fashion. The ends of the shafts can be connected with coupling devices in the form of an integrated coupling flange and mounting devices. The coupling flange can include a mounting surface that extends generally parallel to the axis of rotation of the shaft. Additionally, the coupling flange can include a coupling face that extends generally perpendicular to the axis of rotation, so as to provide a mating face for an adjacent coupling flange to transmit torque from one shaft to another. The mounting flanges can be used to support devices such as solar energy collection devices including photovoltaic modules or other devices.

Abstract: A concentrated solar tower assembly includes a hollow tower structure defining lower and upper portions. The lower portion includes a closable opening region for configuring a closable opening, and the upper portion includes a top gird having inner and outer top grids. The assembly further includes a solar receiver steam generator entirely installed at the ground level G on the inner top grid simultaneous to erection of the tower. The generator on the inner top grid is slidingly directed within the tower from the closable opening to be entirely accommodated therewithin. Thereafter, the generator on the inner top grid is lifted for being placed along the upper portion of the tower.

Abstract: This invention is about a method and apparatus for fabricating large scale stationery parabolic solar collector. The method involves use of a robot like apparatus for determining locations and height of support piles to be staked to the ground such that the tips of the piles define contour and shape of a parabolic collector. The reflective panels installed on the support piles form a parabolic shaped mirror which reflects the sun's rays to a well defined focal point. The method of construction is scalable and can be used for fabricating small size parabolic collectors as well as large scale ones. The construction apparatus and method of operation are also used for periodic cleaning of solar collector in a practical and fast manner.

Abstract: A protective transparent enclosure, such as a greenhouse, encloses a concentrated solar power system having line-focus solar energy concentrators. The line-focus solar energy concentrators have a reflective front layer, a core layer, and a rear layer. The core and the rear layers, when bonded with the reflective front layer, enable the line-focus solar energy concentrator, in some embodiments, to retain a particular form without additional strengthening elements. In some embodiments, the core layer and/or the rear layer are formed by removing material from a single piece of material.

Abstract: A solar panel mount system includes a ballasted block support resting on a ground surface, a post pivoted to the block support at a lower pivot, and a solar panel frame pivoted to the post at an upper pivot with a center of gravity over the ballasted block support and facing a desired sunlight-receiving direction. The upper pivot is selected to be at a desired adjusted height. The frame includes a yoke supported at the upper pivot and support beams supporting a solar panel. A method of installation includes placing the ballasted block support on the ground, and attaching the remaining components at desired angles to locate a center of gravity of the solar panel frame over the ballasted block support, and fixing an angle of the solar panel frame at a desired sun-facing position. A related method includes interconnecting solar panel frames on posts in a generally straight row.

Abstract: Rooftop solar energy module mounting systems that incorporate interchangeable mounting bases with a solar energy module frame.

Abstract: A solar system for collecting solar energy, adapted to be rapidly assembled on site. The modular solar system includes a solar energy collector-assembly, having two wings of collectors, arranged in at least one row. The modular solar system further includes an energy-receiving-module, having a receiver unit, adapted to absorb the solar energy, a shaft, a support structure, a stand, disposed on rigid surface, a control-subsystem, a motor and a sun-following mechanism coupled to operate with the control-subsystem. The receiver unit has a diameter dr, wherein collected energy directed at the external surface of the receiver unit forms a pair of solar energy strips, each strip having a width de, such that de<dr. The solar system may be shipped by land vehicles inside one standard container, wherein each major component is light weight, and can be lifted by two workers.

Abstract: A concentrating solar collector module includes improvements in performance and assemblability. In one configuration, the module includes a reflector having a reflective front surface shaped to concentrate incoming solar radiation onto a focal line, first and second rails, one rail attached to each edge of the reflector, and a set of truss connectors attached to the rails. The truss connectors and rails may form ways that enable constrained sliding engagement of the truss connectors along the rails before attachment of the truss connectors to the rails. The module may also include a plurality of framing members connected to the truss connectors and forming a structural lattice that cooperates with the reflector to lend rigidity to the solar collector module. At least some of the framing members may be disposed in front of the front reflective surface.

Abstract: A system is disclosed that can include an array of solar panels. The array can be arranged into rows of linearly organized modules. The modules can be tilted by a linear actuator attached to a linkage. The tilting can be controlled to maintain a perpendicular orientation between the face of the solar panels (modules) and the direction to the sun.

Abstract: This invention relates to a solar energy collector that converts solar radiation into both electrical and thermal energy. More specifically this invention relates to a concentrating solar energy collector with an integrated construction that minimizes cost, bulk, and weight, and maximizes overall efficiency. Typical non-concentrating solar collectors use photovoltaic cells over the entirety of their surface. These solar cells are the most expensive part of the collector. This invention discloses using a reflector to concentrate the incident radiation on photovoltaic cells with one-twentieth the area of the reflector, and transferring the co-generated thermal energy into a working fluid pumped through the cell support structure.

Abstract: Systems and methods for the automated installation of solar (photovoltaic or PV) modules is disclosed. Embodiments comprise a conveyor system configured to support and deliver a plurality of photovoltaic modules, and a clampless mounting framework comprising an upper rail and a lower rail, the upper and lower rails configured and spaced apart to receive and secure a photovoltaic module. The mounting framework does not require clamps, so once the modules are delivered into place, physical installation is complete.

Abstract: A solar receiver includes a manifold, a sealed enclosure around the manifold and a plurality of tubes connected to the manifold and extending through the sealed enclosure.

Abstract: A solar collector is provided with a frame that is coupled to a based and configured to rotate about a vertical axis. A main panel assembly is attached to the frame and pivotal about a horizontal axis relative to the frame. The main panel assembly receives sunlight and converts the sunlight into electrical energy. The main panel assembly includes a central panel, and a pair of pivotal inner side panels, where each inner side panel is attached to the central panel. A pair of outer side panels attached to the inner side panels is also provided. Each outer side panel includes photo-voltaic (PV) panels, and a panel surround frame for retaining the PV panels. Each panel surround frame has a horizontal channel member, a pair of upright channel members, and a channel bracket, defining a perimeter. A peripheral edge of each PV panel is captured within the channel members.

Abstract: This invention is about a method and apparatus for fabricating large scale stationery parabolic solar collector. The method involves use of a robot like apparatus for sculpting shape of underlying base material to define contour of a parabolic collector. The reflective panels installed on the base material form a parabolic shaped mirror which reflects the sun's rays to a well defined focal point. The method of construction is scalable and can be used for fabricating small size parabolic collectors as well as large scale ones.

Abstract: A method of making a flat plate solar energy system includes steps of: providing a first metal sheet and a second metal sheet; stamping the first metal sheet to create channels; and fabricating a solar panel by joining the first metal sheet to the second metal sheet such that the channels form passageways between the two sheets. The passageways contain the flow of a working fluid that absorbs and transports heat by phase change. The method further includes steps of creating ports to allow the working fluid to enter and exit the solar panel; and providing a heat exchanger piped to the ports of the solar panel. Optional steps include attaching photovoltaic cells to the solar panel; extracting electricity from the photovoltaic cells; and providing a water storage tank.

Abstract: The present invention is premised upon an assembly including at least a photovoltaic sheathing element capable of being affixed on a building structure, the sheathing element including at least: a photovoltaic cell assembly, a body portion attached to one or more portions of the photovoltaic cell assembly; at least a first and a second connector assembly disposed on opposing sides of the sheathing element and capable of directly or indirectly electrically connecting the photovoltaic cell assembly to at least two adjoining devices that are affixed to the building structure and wherein at least one of the connector assemblies includes a flexible portion; one or more connector pockets disposed in the body portion the pockets capable of receiving at least a portion of the connector assembly.

Abstract: A solar tracking assembly includes a spine and a plurality of paired brackets connected to the spine. The brackets are positioned on opposite sides of the spine and at least one of the paired brackets includes wheels to allow rolling movement of the spine. An array arm is attached to each bracket and is moveable from a shipping position to a deployed position, and at least one solar array panel is secured to each array arm. A method of installing a solar panel assembly includes assembling in a secondary automated process at least one solar panel assembly in an offsite location, loading the solar panel assembly in the shipping position on a truck, transporting the truck to a deployment site, and off-loading the solar panel assembly from said truck.

Abstract: A modular assembly comprises a frame formed of a network of elongate members, a deployment skid, an electricity generation skid, at least one foldable door hinged to the frame, and at least one racking assembly attached to the frame. The frame defines a plurality of modular bays including a deployment bay, an electricity generation bay, and at least one energy storage bay. The deployment skid interfaces with the deployment bay, and the solar generation skid interfaces with the solar generation bay. In exemplary embodiments, the electricity generation bay is a solar generation bay and the electricity generation skid is a solar generation skid, at least one photovoltaic module is attached to the racking assembly, and a control unit may be operably connected to the photovoltaic module.

Abstract: A mounting system for a solar array can include a plurality of couplers that are designed to engage and disengage all modules without the use of rails that are greater than the maximum dimension of a solar module. The couplers can be configured to cooperate with height adjuster mechanisms. Additionally, the couplers can be configured to accommodate the engagement and disengagement of solar modules without the need to loosen or remove fasteners, for example, through a hook and tilt movement.

Abstract: An anchor for mounting one or more solar modules to a roof is disclosed. The anchor can comprise a clamp body comprising a central surface and a first arm extending from the central surface. The first arm can have a first clamping face. The clamp body can be sized and shaped to receive at least a first web extending from at least a first solar module such that at least the first web can lie in proximity to the first clamping face. The anchor can further include a clamp member coupled to the clamp body so as to be moveable toward the first clamping face to press the first web against the first clamping face.

Abstract: The present application relates to a method for performing an exhaust cycle of a vacuum solar thermal panel comprising a heating phase of the overall panel up to a maximum temperature (Tm), being the temperature sustainable by at least a panel component. According to the invention it is foreseen a further heating phase being a selective heating phase of some selected panel components, this further heating phase being performed at a second temperature (Th) which is greater than the maximum temperature (Tm).

Abstract: A solar panel mounting system includes a plurality of solar panel support structures which can be formed from solid concrete in adjacent rows with mounting surfaces that are tilted towards the equator. The solar panels can have an adhesive backing which can be used to secure the solar panels directly to the mounting surfaces. The support structures can be made of concrete and formed with a slip form machine. This construction can reduce the time and materials required for the solar panel installation. The solar panel mounting system can also occupy significantly less ground space than conventional solar panel installations.

Abstract: A method for producing a solar heat absorber for a solar collector, the solar heat absorber having a fluid inlet and a fluid outlet. The method includes the steps of providing a first and a second substantially flat metal plate, laser welding the plates together at least along a perimeter of the plates, providing at least a circumferential weld while pressing the plates together, placing the welded plates in a press that provides its pressure at the weld or welds and the press applying a pressure of at least 200 tons per m2 of absorber, and then providing a fluid under a pressure to the absorber via at least one of the fluid inlet and the fluid outlet.

Abstract: A common solar-thermal electric system and a method for assembling the common solar-thermal electric system are provided. The common solar-thermal electric system includes an adjustable mounting rack. The adjustable mounting rack includes a plurality of rails that support at least one solar thermal module and at least one photovoltaic module. Further, the system includes an electric wiring connector with a plurality of connecting ports. The plurality of connecting ports are electrically coupled with electric jacks at each of the at least one photovoltaic module. Furthermore, the system includes a common piping assembly with a plurality of branching points. The plurality of branching points are mechanically coupled with output of each of the at least one solar thermal modules.

Abstract: Producing a solar trough collector includes fastening a mirror to a structure so that the mirror connects to the structure and has a holding container and a mirrored side facing away from the holding container, the mirror and structure forming joining components, aligning the mirror and structure into a joining position to form a joining gap between joining surfaces; at least temporarily fixing the joining components in the joining position by laying the mirrored side downward in a first holding device, suspending the structure in a second holding device arranged above the mirror, and moving holding devices into the joining position; filling the joining gaps with a joining medium; and allowing the joining medium to harden in the gap to form a permanent connection, wherein the holding devices are held in position until the joining medium has at least partially hardened.

Abstract: An absorber tube for solar collectors is provided. The absorber tube comprises a metal tube for carrying and heating a heat transfer medium, a sleeve tube enclosing the metal tube for forming an annular space that can be evacuated, a first container disposed in the annular space and filled with protective gas, an outer ring, and a transition element enclosing the metal tube for sealing off the annular space. The first container includes an outlet opening closed by a closure material, which releases the outlet opening under external actuation for introducing the protective gas into the annular space. The external actuation is applied by an opening unit that is activated for releasing the outlet openings. The first container is fixed in the annular space by a retaining device, which is on the outer ring and/or on the transition element.

Abstract: A solar panel support sub-assembly includes a bottom rail, a first top rail and a second top rail, each rail having first and second longitudinally opposite ends. The first end of the bottom rail is pivotally coupled to the first end of the first top rail and the second end of the bottom rail is pivotally coupled to the first end of the second top rail. The sub-assembly also includes a ballast rail having a first end that is pivotally coupled to the bottom rail at a first location intermediate the first and second longitudinally opposite ends of the bottom rail. The sub-assembly may be unfolded for assembly by pivoting the first and second top rails within a first plane and pivoting the ballast rail within a second plane that is normal to the first plane.

Abstract: One embodiment of the invention relates to a light concentrator apparatus including a reflector with an open substantially hemispherical reflecting surface characterized by a radius R, and an aperture for admitting light onto the hemispherical reflecting surface. The light concentrator apparatus further includes a movable elongated light collector having a first end located proximal to the reflecting surface; and extending along a longitudinal axis in a direction substantially normal to the reflecting surface to a second end. The light concentrator further includes a tracker configured to move the first end of the collector to points proximal to the reflecting surface.

Abstract: Embodiments of the invention provide systems, devices, and methods for mounting a photovoltaic module to a structure, such as a roof. An embodiment of a method for mounting a photovoltaic module to a structure may include providing a photovoltaic module, a first mounting device, and a second mounting device. The first mounting device and the second mounting device may be coupled with the structure, such as a roofing membrane, so that opposing mounting channels of the respective devices face one another. The method may further include inserting a first edge of the photovoltaic module within the mounting channel of the first mounting device and inserting a second edge of the photovoltaic module within the mounting channel of the second mounting device so that the photovoltaic module is disposed between the first mounting device and the second mounting device.

Abstract: Coil solar receiver for a Stirling disk, the main components of which are pipes (where the sun hits), collectors, tanks and cupolas (of which there are two types, one that houses the regenerator, and the expansion cupola that is the area where the working gas is at a higher temperature) that includes a series of pipes (1) that perpendicularly exit from one collector (2) and perpendicularly enter another (2) and where each pipe consists of two semicircumferential curved parts (10) and three straight parts (11) parallel to one another: a center straight part (between curve and curve) and two straight parts on the ends (between the curve and the exit of one collector (2)), the two straight end parts being located on the same plane, while the center straight part is located in a separate plane.

Abstract: A transportable photovoltaic system includes a plurality of photovoltaic devices, a composite frame to which the plurality of photovoltaic devices are affixed, and a base structure to which the composite frame is movably attached through at least one variable-angle mount structure. The orientation of the frame and the light concentrating elements relative to the base structure can be altered employing the at least one variable-angle mount structure. The frame and the plurality of photovoltaic devices can be assembled prior to shipping, and the base structure can be manufactured on site. The transportable photovoltaic system is not affixed to ground or other fixture, but can be picked up at any time during the operational lifetime. The transportable photovoltaic system can be rapidly deployed with little or no site preparation requirement other than generally level ground, and can be retracted to a lower exposure position to avoid storm and/or hazardous conditions.

Abstract: A solar ballasted racking system holds hot water flat plate solar collectors in place on flat roofs without penetrating the roof surface. The racking system also holds the collector in place, providing a stable, long-term placement on the roof while protecting the roof surface with foam pads placed under the ballast tray. The ballast tray is built in two sections—one to hold the solar collector in place and a second to act as a wind deflector that deflects the wind off the solar collector. Ballast blocks are added into the ballast tray to hold the collector in place. The racking system may enhance the life of the roof while protecting the roof surface and allowing for lower ballasted weights due to the wind deflector.

Abstract: An attachment system is provided. In another aspect, an elongated member is inserted through support assembly to secure the support assembly to a building roof. Another aspect employs a bracket having a guide pin that engages a pin receptacle on a stand as the bracket is lowered onto the stand. A method of attaching a solar panel to a building is additionally provided.

Abstract: Various embodiments provide an absorber tube that comprises an inner tube having an exterior surface, at least a portion of which contains a plurality of coating layers. The absorber tube also includes an outer tube spaced apart from the inner tube so as to define a cavity between the two. At least one of the coating layers may be configured to substantially impede migration of gaseous particles from the interior surface and into said cavity. At least one of the coating layers may be a reflective copper coating that is adhered to the exterior surface via an electrical charging process. An absorber tube comprising a connecting member between central and end portions of the tube is also provided. The central portion may be formed from carbon steel, while remaining portions are formed from stainless steel. Coating layers may be likewise adhered to only the central portion.

Abstract: The invention relates to a mounting system, which is configured for mounting at least one photovoltaic module (20) and a solar collector (30) on a substructure suitable therefor. The mounting system (1) comprises at least one U-shaped mounting carrier (2) for fastening the at least one photovoltaic module (20) and for accommodating at least one solar collector (30), the U-shaped mounting support being fastened to the substructure by means of a mounting rail (3), wherein the mounting carrier (2) has support clamping receptacles (9) for fastening the at least one photovoltaic module (20) to at least one of the outer surfaces of the mounting carrier.

Abstract: A photovoltaic mounting apparatus includes a mounting frame coupled to a pile capable of being anchored in numerous terrain and slope conditions, universal clamping for mounting any type of solar panel thereto, and components enabling customized angles of inclination of photovoltaic modules mounted onto the frame. Optimized testing and preparation for installation are part of a process ensuring that design of materials and installation of a photovoltaic mounting apparatus is customizable to reduce time and expense in a method of installation.

Abstract: A solar collector system is provided including a bearing assembly comprising a plurality of wheels or rollers for rollingly engaging a large-diameter support element. Rotation of the large-diameter support element supports tracking of the position of the sun relative to the solar collector system. The bearing assembly may be pre-assembled to the large-diameter support element before the solar collector system leaves the factory, thereby facilitating assembly of the solar collector system in the field, even under adverse conditions.

Abstract: Systems and methods may be provided for supporting a solar module. A torque tube may be provided with one or more longitudinal outrigger extensions which may extend beyond an end of the torque tube. In some embodiments, the torque tube does not extend all the way to the edge of the solar module.

Abstract: A method of installing a solar energy system comprises laying an uninflated elongated tube of flexible material in a substantially flat configuration, winding the uninflated elongated tube on a spool, transporting the spool with the elongated tube, and filling the elongated tube with a gas and/or liquid such that the elongated tube inflates with the gas and/or liquid and unrolls from the spool.

Abstract: A photovoltaic power system includes a flexible panel (105) comprising a plurality of photovoltaic cells (305) configured to convert solar energy into electrical energy. The photovoltaic power system also includes an inflatable support frame (110) coupled to the flexible support panel, where the inflatable support frame is configured to support to the flexible panel when inflated by a gaseous solution. In addition, the photovoltaic power system may include a control canister (115) configured to store the gaseous solution and to provide the gaseous solution to the inflatable support frame.