Product  Application

Efficient land use: It can utilize barren hills and slopes, without occupying arable land or urban land. Moreover, the flexible support technology can adapt to complex terrain, and its high clearance and large span layout can improve land utilization efficiency, saving 30%-50% of land compared to traditional supports.

High power generation efficiency: Due to the high altitude and minimal obstruction, mountainous areas enjoy good lighting conditions. Furthermore, the installation angle and orientation of components can be optimized according to the terrain to fully capture sunlight. Simultaneously, the fresh air and lower temperatures in mountainous regions contribute to extending the lifespan and enhancing the efficiency of photovoltaic panels.

Environmentally friendly: The coverage of photovoltaic modules can reduce evaporation from surface sunlight, increase soil moisture and organic content, and facilitate vegetation growth. Moreover, photovoltaic power generation has zero emissions, which can reduce greenhouse gas emissions and improve environmental quality.

Good economic benefits: Photovoltaic panels can be installed on a large scale to increase the total power generation. The use of technologies such as flexible supports can reduce the amount of pile foundation construction and steel usage, thereby lowering initial investment and construction costs and enhancing economic benefits.

It refers to the integration of fish farming and photovoltaic power generation, where photovoltaic panel arrays are erected above the surface of fish ponds, allowing fish and shrimp farming in the waters below. The front side of the photovoltaic panels also provides good shelter for fish farming, forming a new power generation model of "generating electricity above and farming fish below", achieving a win-win situation for both photovoltaic power generation development and fish farming.

Advantages of the fish-solar complementary structure: This model, which combines power generation on water and fish farming underwater, allows for both the income from aquaculture and the benefits of photovoltaic power generation. One piece of land yields two harvests, greatly improving land utilization. By fully utilizing the space beneath photovoltaic modules, the system achieves a high panel layout rate, and the module orientation can be adjusted. Under the same power station capacity conditions, it can effectively save land and help better utilize land resources.

It refers to the integration of livestock farming and photovoltaic power generation, where photovoltaic panel arrays are erected above the livestock farm, and the area below the panels can be used for livestock breeding. The front side of the photovoltaic panels can also provide good shading for the area, forming a new power generation model of "breeding under the shed and generating electricity above the shed", achieving a win-win situation for both photovoltaic power generation development and livestock farming.

Advantages of solar pasture: Solar panels installed on pastures have the effects of preventing wind and sand, reducing evaporation, and improving disaster conditions, providing good protection for grassland ecology.

The "Pastoral-Photovoltaic Complementary" model enables residents to diversify their income sources beyond traditional animal husbandry, and also allows them to profit from the photovoltaic power generation industry, thereby enhancing the overall benefits of the region.

Installing a photovoltaic power station on the ranch, photovoltaic panels can shield the scorching sun, block the wind and sand, and prevent the destruction of the ranch and surrounding ecological environment caused by wind and sand weather. They can also provide protection for the animals being raised. Under the photovoltaic panels, the grass grows well, providing an abundant source of feed for the livestock.

BIPV photovoltaic support carport is the simplest and most feasible way to combine photovoltaics with architecture. Photovoltaic carports have good heat absorption, are easy to install, and save costs. They not only make full use of existing space but also provide green and environmentally friendly energy. Constructing photovoltaic carports in factory parks, commercial areas, hospitals, schools, etc. can solve the problem of high temperatures inside vehicles in open parking lots during summer. They provide protection for vehicles from the sun and rain, reduce damage to the vehicle's appearance from ultraviolet rays and acid rain, and extend the vehicle's service life.

Energy-saving in power generation involves installing photovoltaic panels on the top of the carport to convert solar energy into electrical energy. This can supply power for lighting and charging facilities inside the carport, and excess electricity can also be fed into the grid, achieving both energy conservation and economic benefits. The combination of photovoltaic panels and water gutters forms structural waterproofing. The installation is convenient and the waterproof performance is excellent. Most of the brackets are pre-installed in the factory, ensuring quick construction and convenient maintenance in the later stages.

The space utilization rate is high, fully utilizing the idle space above the carport to achieve power generation without occupying additional land resources.

The dual utilization of the carport function has improved the comprehensive utilization rate of space.