2813results about "Solar heat collectors safety" patented technology

A tracking solar power system is disclosed. The tracking solar power system includes: a solar power substructure and a platform having a first degree of freedom. The solar power substructure is mounted on the platform in a manner such that it has a second degree of freedom relative to the platform. The solar power substructure may include a solar collector and a receiver arranged to receive energy from the solar collector. The receiver may be mounted in a manner that avoids shading of the solar collector during operation. The solar collector may have an area focus at the receiver. The solar power substructure may include a non-concentrating solar power substructure.

The solar energy and solar farms are used to generate energy and reduce dependence on oil (or for environmental purposes). The maintenance and repairs in big farms become very difficult, expensive, and inefficient, using human technicians. Thus, here, we teach using the robots with various functions and components, in various settings, for various purposes, to improve operations in big (or hard-to-access) farms, to automate, save money, reduce human mistakes, increase efficiency, or scale the solutions to very large scales or areas.

A barrier, such as a PV module, is secured to a base by a support to create a shingle assembly with a venting region defined between the barrier and base for temperature regulation. Water resistant junctions may be formed between the bases of adjacent shingle assemblies of an array of shingle assemblies. The base may include an insulation layer underlying a water barrier. The base may also include a waterproofing element; the width and height of the barrier may be shorter than the width and height of the waterproofing element.

PV modules are provided that have a frame construction which permits the photovoltaic power-generating cells, DC / AC power conversion means, electrical wiring and other installation aspects to be merged into the module. The modules also are provided with means for coupling them to mounting stands whereby they can be mounted to a roof and also the frame construction is adapted to facilitate mechanically securing adjacent modules to one another.

A support system for photovoltaic cells upon a roof. A cell support structure is provided beneath each cell, such as in the form of a pair of brackets to form a photovoltaic panel. The panels overlap partially to function somewhat as shingles, to shed water off of the roof. A lower side wall of each photovoltaic panel has at least one port therein to selectively access a space beneath the photovoltaic cell. Photovoltaic cell electronics, such as an inverter for one or a series of cells. A door is provided in one embodiment which selectively covers the port and acts as a support for the photovoltaic cell electronics.

Disclosed are fixed solar-electric modules having arrays of solar concentrator assemblies capable of separately tracking movements through one or two degrees of rotational freedom to follow the movement of the sun daily and / or seasonally. The concentrators can include optical elements to direct and concentrate light onto photovoltaic and / or thermoelectric receivers for generation of electric current.

A barrier, such as a PV module, is secured to a base by a support to create a shingle assembly with a venting region defined between the barrier and base for temperature regulation. The first edge of one base may be interengageable with the second edge of an adjacent base to be capable of resisting first and second disengaging forces oriented perpendicular to the edges and along planes oriented parallel to and perpendicular to the base. A deflector may be used to help reduce wind uplift forces.

Fluid delivery systems and related structures and processes are provided, such as for use with water, treated water, and / or a cleaning solution, for any of cleaning, cooling or any combination thereof, for one or more solar panels in a power generation environment. Enhanced coatings are provided for the incident surface of solar panels, such as to avoid build up of dirt, scale, or other contaminants, and / or to improve cleaning performance. Reclamation, filtration, and reuse structures are preferably provided for the delivered fluid, and seal structures may preferably be implemented between adjoining panels, to minimize loss of the delivered water or cleaning solution. The fluid delivery system may preferably be linked to an automated control system, such as but not limited to integrated DMPPT modules and related systems.

An integrated module frame and racking system for a solar panel is disclosed. The solar panel comprises a plurality of solar modules and a plurality of splices for coupling the plurality of solar modules together. The plurality of splices provide a way to make the connected modules mechanically rigid both during transport to the roof and after mounting for the lifetime of the system, provide wiring connections between modules, provide an electrical grounding path for the modules, provide a way to add modules to the panel, and provide a way to remove or change a defective module. Connector sockets are provided on the sides of the modules to simplify the electrical assembly of modules when the modules are connected together with splices.

Rectangular PV modules (6) are mounted on a building roof (4) by mounting stands that are distributed in rows and columns. Each stand comprises a base plate (10) that rests on the building roof (4) and first and second brackets (12, 14) of different height attached to opposite ends of the base plate (10). Each bracket (12, 14) has dual members for supporting two different PV modules (6), and each PV module (6) has a mounting pin (84) adjacent to each of its four corners. Each module (6) is supported by attachment of two of its mounting pins (84) to different first brackets (12), whereby the modules (6) and their supporting stands are able to resist uplift forces resulting from high velocity winds without the base plates (10) being physically attached to the supporting roof structure (4). Preferably the second brackets (14) have a telescoping construction that permits their effective height to vary from less than to substantially the same as that of the first brackets (12).

Provided is a consumer to industrial scale renewable energy based quintuple-generation systems and energy storage facility. The present invention has both mobile and stationary embodiments. The present invention includes energy recovery, energy production, energy processing, pyrolysis, byproduct process utilization systems, separation process systems and handling and storage systems, as well as an open architecture for integration and development of additional processes, systems and applications. The system of the present invention primarily uses adaptive metrics, biometrics and thermal imaging sensory analysis (including additional input sensors for analysis) for monitoring and control with the utilization of an integrated artificial intelligence and automation control system, thus providing a balanced, environmentally-friendly ecosystem.

A solar power system is mounted to a solar power componentry support structure (104) suspended above a pre-existing surface (101) by a collective of solar collector suspension base supports (103) Suspended solar power system row support structure members (105) and suspended solar power system column support structure members (106) may for a solar component position lattice (107) to which a matrix of individual solar power components such as solar panels (18) can be attached Solar module quick-fasten assemblages (111) may serve also as solar componentry emergency releases (118) and may include loose axis retainers (128) and firm axis fasteners (127) such as dual component, single point operative emergency releases (121) and fasteners Slide-in retainers and corner slot tabs (136) can be included as well as frame alignment notches (138) Fulcrum pivot fasteners (139) and slide wedge releases (142) can aid in installation and release

A collapsible PV assembly comprises a PV module, a front support and a rear support assembly. The front and rear supports are secured to the front and rear edges of the PV module. The rear support assembly comprises a wind deflector assembly including a wind deflector which can be placed in a downwardly and outwardly extending use orientation and a storage orientation, extending along the lower surface of the PV module. In some embodiments the wind deflector assembly is pivotally connected to the PV module.

The present invention relates to photovoltaic concentrating modules and related concentrating solar systems and methods. In particular, the present invention relates to concentrating modules, especially modules having a convenient size and market acceptance of traditional flat photovoltaic solar panels.

An apparatus and method for collecting solar energy are provided. The apparatus is a trough-type solar collector having one or more mirrors and lenses for directing solar radiation toward a receiver configured to receive a heat transfer fluid therein. The amount of solar radiation directed toward the receiver can be controlled by adjusting one or more of the mirrors and / or lenses or by adjusting a shade. Thus, the collector can direct different amounts or solar radiation toward the receiver, thereby selectively heating the receiver at different rates, e.g., to preheat the receiver, to heat fluid in the receiver for power generation, or to thaw solidified fluid in the receiver. Subsequently, the heated fluid can be used to generate steam and / or electricity.

A modular shade system with solar tracking panels includes a series of generally North-South oriented, spaced apart torque tubes, each torque tube having an axis, a series of panels mounted to at least some of the torque tubes to create spaced-apart rows of panels along the torque tubes, at least some of the panels being solar collector panels. The system also includes a shade structure, positioned at a selected location between selected ones of the torque tubes and above the support surface so to provide an enhanced shaded region thereunder, and a support structure. The support structure includes a first mounting assembly mounting each torque tube above the support surface for rotation about the axis of each torque tube and a second mounting assembly supporting the shade structure at the selected location. The system further comprises a tilting assembly selectively rotating each torque tube about its axis.

A solar array mounting system having unique installation and grounding features, and which is adaptable for mounting solar panels having mounting holes located in different locations. The solar array mounting system includes tilt brackets and longitudinal links forming columns. A tilt bracket includes a tilt arm for supporting an upper spar of one row, and a pivot block for supporting a lower spar of a next row. The spars may be made from extruded aluminum or from steel, wherein the steel spars include an exposed metal channel to provide a common electrical equipment ground. Panel clamps are used to clamp the solar panel frames to the spars, allowing for variations in mounting hole locations.

A photovoltaic roofing assembly comprises a roofing membrane (102), a plurality of photovoltaic modules (104, 106, 108) disposed as a layer on top of the roofing membrane (102), and a plurality of pre-formed spacers, pedestals or supports (112, 114, 116, 118, 120, 122) which are respectively disposed below the plurality of photovoltaic modules (104, 106, 108) and integral therewith, or fixed thereto. Spacers (112, 114, 116, 118, 120, 122) are disposed on top of roofing membrane (102). Membrane (102) is supported on conventional roof framing, and attached thereto by conventional methods. In an alternative embodiment, the roofing assembly may have insulation block (322) below the spacers (314, 314′, 315, 315′). The geometry of the pre-formed spacers (112, 114, 116, 118, 120, 122, 314, 314′, 315, 315′) is such that wind tunnel testing has shown its maximum effectiveness in reducing net forces of wind uplift on the overall assembly. Such construction results in a simple, lightweight, self-ballasting, readily assembled roofing assembly which resists the forces of wind uplift using no roofing penetrations.

Pressure equalization between upper and lower surfaces of PV modules of an array of PV modules can be enhanced in several ways. Air gaps opening into the air volume, defined between the PV modules and the support surface, should be provided between adjacent PV modules and along the periphery of the array. The ratio of this air volume to the total area of the air gaps should be minimized. Peripheral wind deflectors should be used to minimize aerodynamic drag forces on the PV modules. The time to equalize pressure between the upper and lower surfaces of the PV modules should be maintained below, for example, 10-20 milliseconds. The displacement created by wind gusts should be limited to, for example, 2-5 millimeters or less. For inclined PV modules, rear air deflectors are advised for each PV module and side air deflectors are advised for the periphery of the array.

A lightweight photovoltaic concentrator is disclosed. The concentrator comprises at least two sections each comprising a cell panel, a radiator panel and a reflector panel. In one embodiment, the concentrator system of the present invention comprises at least two hinged sections each comprising a solar cell panel, a flat radiator panel, and a curved reflective concentrator panel. The solar cell panel comprises at least one photovoltaic cell for generating electrical power in response to radiation. The solar cell panel is aligned with the radiator panel at an angle less than 180 degrees but not less than 90 degrees facing the reflective concentrator panel. In another embodiment, the cell panels on adjoining sections are angled in opposite directions with respect to the radiator panels and wherein the reflective concentrator panels are located on opposite sides of the radiator panels. A heat pipe or loop heat pipe is located in the radiator panel to dissipate heat from the solar cells.

An automatic cleaning system for solar panels has a time controller, a detection device, a perfusion device, a driving device and a cleaning device. Based on predetermined time values, execution signals are sent to the perfusion device, the driving device and the detection device to implement prompt assessment of the need for cleaning and cleaning, if warranted. Also provided is an automatic cleaning method using the system.

A two-axis solar tracker is capable of withstanding extreme weather conditions. The solar tracker includes a solar array, a frame, a base, a pivot frame, and a first and second actuator. The solar array is mounted to the frame and captures sunlight. The base is pivotally connected to the frame and defines a pivot axis for elevational movement of the solar array. The pivot frame is also pivotally connected to the frame and defines a pivot axis for azimuthal movement of the solar array. The first actuator controls elevational movement of the solar array and the second actuator controls azimuthal movement of the solar array. The solar tracker is pivotable between a raised position and a stowed position.

System and method for cleaning rows of solar panels. Each solar row has an upper edge elevated above ground level and a lower edge to provide an inclination of the solar row. A cleaning assembly cleans the solar panel surfaces. A support frame supports the cleaning assembly and enables upward and downward motion in the width and length directions of the solar row. Operation and movement of the cleaning assembly is controlled so as to clean a surface of the solar panels during downward movement. The cleaning assembly is preferably not operative during upward movement. During downward movement, the cleaning assembly removes dirt, debris and dust from the surface of the solar panels and generates an air stream to blow off the dirt, debris, and dust. The system further includes a guide system for moving the cleaning assembly to align with successive solar panel rows.

A concentrator solar photovoltaic power generating apparatus including a primary optics for concentrating sunlight, a solar cell, a columnar optical member which is vertically disposed above the solar cell so that a bottom end surface of the columnar optical member is opposed to the solar cell, and which is used for guiding the sunlight which is concentrated by the primary optics to the solar cell, a transparent resin member which is interposed between the bottom end surface of the columnar optical member and the solar cell, comprises a shielding member for shielding the transparent resin member from sunlight.

An extensive photovoltaic array for generating electric power from concentrated solar radiation, formed of an extensive planar structural grid wherein a multitude of power generating modules are installed, said structural grid being positioned by a primary servomechanism to keep incident solar radiation perpendicular to the plane of the array at all times.

A receiver for a system for generating electrical power from solar radiation is disclosed. The systems includes the receiver and a means (3) for concentrating solar radiation onto the receiver. The receiver includes a plurality of photovoltaic cell modules. Each module includes a plurality of photovoltaic cells (5), and includes an electrical connection that forms part of the receiver electrical circuit. The receiver includes a coolant circuit for cooling the photovoltaic cells with a coolant. The coolant circuit includes a coolant flow path in each module that is in thermal contact with the photovoltaic cells so that in use coolant flowing through the flow path extracts heat from the photovoltaic cells and thereby cools the cells.

An apparatus and method for collecting solar energy are provided. The apparatus is a trough-type solar collector having one or more mirrors and lenses for directing solar radiation toward a receiver configured to receive a heat transfer fluid therein. The amount of solar radiation directed toward the receiver can be controlled by adjusting one or more of the mirrors and / or lenses or by adjusting a shade. Thus, the collector can direct different amounts or solar radiation toward the receiver, thereby selectively heating the receiver at different rates, e.g., to preheat the receiver, to heat fluid in the receiver for power generation, or to thaw solidified fluid in the receiver. Subsequently, the heated fluid can be used to generate steam and / or electricity.