A method for increasing the energy output of an already installed solar power plant is provided including at least one first solar panel, which is absorbing sunlight in a first frequency band, wherein a semi-transparent second solar panel, which absorbs light in a second frequency band, is mounted on top of at least one of the at least one first solar panel and connected to a power electronics device of the solar power plant including at least one solar inverter, wherein the first and second frequency bands do not or only partially overlap such that the second solar panel allows at least a part of the light of the first frequency band to pass.

A solar tracking system comprises multiple solar panel modules forming a grid of solar panel modules, wherein the multiple solar panel modules are orientatable to a solar source independently of each other; and a control system configured to orient each of the multiple solar panel modules to the solar source independently of each other based on a performance model to optimize an energy output from the grid of solar panel modules, wherein the performance model predicts an energy output from the grid of solar panel modules based on a topography of the area containing the grid of solar panel modules and weather conditions local to each of the solar panel modules.

The present invention provides a full-azimuth irradiation tracking method, a detection apparatus, and a solar tracker. The method comprises: acquiring a multi-azimuth irradiation data combination in a full-azimuth irradiation tracking mode; calculating a target tracking angle with a maximum irradiation amount among a plurality of azimuths according to the multi-azimuth irradiation data combination, and rotating the solar tracker according to the target tracking angle; collecting irradiation data at a position reached after the solar tracker is rotated, and calculating and analyzing whether the solar tracker is rotated and reaches a target position corresponding to the target tracking angle; and when the solar tracker is rotated and reaches the target position corresponding to the target tracking angle, controlling the solar tracker to maintain for a preset time at the target position. By means of the described solution, the multi-azimuth irradiation data combination can be obtained in the full-azimuth irradiation tracking mode, and an optimal tracking angle can be obtained by analyzing and determining, so that the solar tracker obtains the maximum irradiation amount and maintains for the preset time, thereby being able to increase a power generation amount.

A system includes a tracker configured to collect solar irradiance and attached to a rotational mechanism for changing a plane of the tracker and a controller. The controller is programmed to store a plurality of positional and solar tracking information and detect a first amount of DHI and a first amount of DNI at a first specific point in time. If the first amount of SHI exceeds the first amount of DNI, the controller is programmed to calculate a first angle for the tracker to maximize an amount of irradiance received by the tracker. Otherwise, the controller is programmed to calculate the first angle for the tracker based on a position of the sun associated with the first specific point in time and the plurality of positional and solar tracking information.

A solar tracker system includes a support tube, a solar panel assembly connected to the support tube, and an active lock connected to the support tube. The active lock includes a housing defining a chamber and a seal. The seal prevents a flow of fluid through the chamber when the active lock is in a sealed state and allows the flow of fluid through the chamber when the active lock is in an unsealed state. The active lock further includes a locking system motor connected to the seal to transition the active lock between the sealed state and the unsealed state, a battery providing power to the locking system motor, and an antenna for receiving instructions controlling the locking system motor.

Disclosed are a plant growth management system and a control method thereof. A station device of the plant growth management system includes a flowerpot detector configured detect entry of a movable flowerpot device and to generate a detection signal according to whether entry of the movable flowerpot device is detected, a wireless charger configured to wirelessly supply power to the movable flowerpot device according to the detection signal, and a water supply device configured to supply water to a flowerpot included in the movable flowerpot device according to the detection signal, wherein the movable flowerpot device includes an obstacle detection sensor and a solar detection sensor, performs autonomous driving based on the obstacle detection sensor and the solar detection sensor, searches for a space, an illuminance value of which is equal to or greater than a preset illuminance value, through the autonomous driving, and performs rotational motion in the searched space.

A method of controlling a solar array including receiving current and voltage data from a plurality of solar modules of the solar array, calculating a diffuse fraction irradiance for the plurality of solar modules, mapping the diffuse fraction irradiance for the plurality of solar modules, generating a digital image of light conditions in the solar array based on the mapped diffuse fraction irradiance, defining zones within the array based on the light conditions in the digital image, determining a zone-specific solar tracker angle for each zone based on mapped diffuse fraction irradiance, transmitting the zone-specific solar tracker angle to a computing device associated with each solar tracker in the solar array, and driving the solar trackers of each zone such that the solar trackers that make up each zone are oriented to substantially the same angle.

A solar tracker system includes a photovoltaic panel and an actuator coupled to the photovoltaic panel and configured to actuate to rotate the photovoltaic panel around a base. A controller communicatively coupled to the actuator is configured to detect a direction from which wind is incident on the photovoltaic panel. Based on the direction from which wind is incident on the photovoltaic panel, the controller adaptively controls the actuator to set a stow position of the photovoltaic panel.

A system is provided. The system includes a tracker configured to collect solar irradiance and attached to a rotational mechanism for changing a plane of the tracker and a controller in communication with the rotational mechanism. The controller is programmed to store a plurality of positional information and a shadow model for determining placement of shadows based on positions of objects relative to the sun, determine a position of the sun at a first specific point in time, retrieve height information for the tracker and at least one adjacent tracker, execute the shadow model based on the retrieved height information and the position of the sun, determine a first angle for the tracker based on the executed shadow model, and transmit instructions to the rotational mechanism to change the plane of the tracker to the first angle.

A method may include calculating a solar position of the Sun and a projected solar zenith (PSZ) relative to a position of a photovoltaic (PV) module. The method may include determining whether an orientation of the PV module is configurable to prevent shading of an upper substring of the PV module while shading a lower substring of the PV module. Responsive to determining that such an orientation is not configurable, the method may include determining whether the orientation of the PV module is configurable to prevent shading of both the upper substring and the lower substring. Responsive to determining that such an orientation is not configurable, the method may include determining whether the PSZ is within a maximum tracker angle range. A target tracker angle may be identified based on the PSZ and the maximum tracker angle range and used as a tracker angle control setpoint.