A solar panel washing assembly for automatically cleaning solar panels includes a plurality of solar panels that is each positionable on a support surface to be exposed to sunlight. A fluid supply pipe is fluidly coupled to a pressurized water source w to receive pressurized water and a control unit is positioned proximate the support surface. The control unit is fluidly coupled to the fluid supply pipe to receive the pressurized water. A plurality of distribution pipes is each fluidly coupled to the control unit to receive the pressurized water when the control unit actuated into the open condition. A plurality of spray nozzles is each fluidly coupled to a respective one of the distribution pipes to spray the pressurized water onto a respective solar panel to clean the respective solar panel.

A hardened solar thermal energy collector (STEC) system that is adapted to withstand a nuclear detonation or other powerful explosion in the vicinity. The STEC system comprises a plurality of collector tubes arranged side by side in an array that carry and circulate a working fluid, each of the plurality of collecting tubes having an upper radiation collection surface having a diffractive optical structure and a bottom surface, a supporting tray upon which each of the collector tubes is securely mounted, an insulated housing set beneath a ground surface level enclosing the plurality of collector rubes and supporting trays, and a secured underground geothermal storage unit fluidly coupled to the array of collector tubes. The housing, the plurality of collector tubes, and the tray are positioned such that topmost portions thereof are at the ground surface level or below.

A monitoring system that is configured to monitor a property is disclosed. The monitoring system includes a sensor that is configured to generate sensor data that reflects an attribute of the property; a solar panel that is configured to generate and output power; and a monitor control unit. The monitor control unit is configured to: monitor the power outputted by the solar panel; determine that the power outputted by the solar panel has deviated from an expected power range; based on determining that the power outputted by the solar panel has deviated from the expected power range, access the sensor data; based on the power outputted by the solar panel and the sensor data, determine a likely cause of the deviation from the expected power range; and determine an action to perform to remediate the likely cause of the deviation from the expected power range.

A robot for cleaning solar panels has a frame and a propulsion system for moving the robot on solar panels. The robot also has arms movably coupled to the frame, and a cleaning assembly coupled to each of the arms for cleaning the solar panels. The arms and cleaning assemblies further facilitate the transportation of the robot between solar panels that are discontinuous and spaced apart from each other. In addition, a water distribution system is included for distributing water during cleaning operations. A control system operates the robot and controls the propulsion system, arms, cleaning assemblies and water distribution system.

A robot for cleaning solar panels has a frame and a propulsion system for moving the robot on solar panels. The robot also has arms movably coupled to the frame, and a cleaning assembly coupled to each of the arms for cleaning the solar panels. The arms and cleaning assemblies further facilitate the transportation of the robot between solar panels that are discontinuous and spaced apart from each other. In addition, a water distribution system is included for distributing water during cleaning operations. A control system operates the robot and controls the propulsion system, arms, cleaning assemblies and water distribution system.

A solar tracker waterless cleaning system for cleaning solar panels of a solar tracker being able to be positioned at a pre-determined angle, including a docking station and an autonomous robotic cleaner (ARC), the docking station coupled with an edge of the solar tracker, the ARC including at least one rechargeable power source, at least one cleaning cylinder, at least one edge sensor, at least one cleaning cylinder direct current (DC) drive motor including a built-in encoder, a cleaning cylinder drive belt and a controller, the cleaning cylinder including a plurality of fins which rotates for generating a directional air flow for pushing dirt off of the surface of the solar tracker without water, the cleaning cylinder DC drive motor for driving the cleaning cylinder, the controller for controlling a cleaning process of the ARC, the built-in encoder for determining a revolutions per minute (RPM) of the cleaning cylinder.

A rotary-wing drone and a method of blowing air by an air blowing device integrated with the rotary-wing drone are described. The rotary-wing drone includes a plurality of rotary propellers, an extendable cone, a centrifugal propeller unit, and one or more batteries, in the air blowing device. The rotary-wing drone further includes a camera configured to obtain images of surrounding environment of the rotary-wing drone, and a processing circuitry configured to analyze the images to determine dust characteristics on a solar panel and to obtain one or more parameters of the air blowing device and the rotary-wing drone, to enable the rotary-wing drone to clean the solar panel.

A rotary-wing drone and a method of blowing air by an air blowing device integrated with the rotary-wing drone are described. The rotary-wing drone includes a plurality of rotary propellers, an extendable cone, a centrifugal propeller unit, and one or more batteries, in the air blowing device. The rotary-wing drone further includes a camera configured to obtain images of surrounding environment of the rotary-wing drone, and a processing circuitry configured to analyze the images to determine dust characteristics on a solar panel and to obtain one or more parameters of the air blowing device and the rotary-wing drone, to enable the rotary-wing drone to clean the solar panel.

A solar heat collection device for a near-zero energy consumption community, including a heat collection frame, a heat collector, a center of gravity adjusting frame and a self-adaptive angle adjusting assembly, wherein the heat collector is rotatably disposed on the heat collection frame through the self-adaptive angle adjusting assembly; the center of gravity adjusting frame is fixed on one side of the bottom of the heat collector; the self-adaptive angle adjusting assembly includes a fixing cylinder, an angle adjusting cylinder, an inner cylinder and a damping adjusting assembly; the inner cylinder is coaxially fixed inside the angle adjusting cylinder; two ends of the angle adjusting cylinder are respectively coaxially and rotatably connected with the fixing cylinder; and the damping adjusting assembly is arranged between the angle adjusting cylinder and the fixing cylinder.

A solar heat collection device for a near-zero energy consumption community, including a heat collection frame, a heat collector, a center of gravity adjusting frame and a self-adaptive angle adjusting assembly, wherein the heat collector is rotatably disposed on the heat collection frame through the self-adaptive angle adjusting assembly; the center of gravity adjusting frame is fixed on one side of the bottom of the heat collector; the self-adaptive angle adjusting assembly includes a fixing cylinder, an angle adjusting cylinder, an inner cylinder and a damping adjusting assembly; the inner cylinder is coaxially fixed inside the angle adjusting cylinder; two ends of the angle adjusting cylinder are respectively coaxially and rotatably connected with the fixing cylinder; and the damping adjusting assembly is arranged between the angle adjusting cylinder and the fixing cylinder.