Abstract: A multi-compartment bed radial flow adsorber capable of realizing large telescopic deformation mainly comprises an adsorber body, the adsorber body consists of an upper seal head, a barrel, a lower seal head and a pressed shell connected with an upper connecting pipe and a lower connecting pipe, the upper seal head and the lower seal head of the shell are each provided with an upper gas inlet and outlet pipe and a lower gas inlet and outlet pipe, a supporting seat is arranged at the bottom in the shell, an adsorption barrel is arranged above the supporting seat and consists of a plurality of concentric barrels with different diameters, a plurality of annular spaces are formed by the concentric barrels with different diameters, different types of adsorbents can be filled in the annular spaces, and the adsorption barrel is composed of a pore plate or a grid.

Abstract: A multi-compartment bed radial flow adsorber capable of realizing large telescopic deformation mainly comprises an adsorber body, the adsorber body consists of an upper seal head, a barrel, a lower seal head and a pressed shell connected with an upper connecting pipe and a lower connecting pipe, the upper seal head and the lower seal head of the shell are each provided with an upper gas inlet and outlet pipe and a lower gas inlet and outlet pipe, a supporting seat is arranged at the bottom in the shell, an adsorption barrel is arranged above the supporting seat and consists of a plurality of concentric barrels with different diameters, a plurality of annular spaces are formed by the concentric barrels with different diameters, different types of adsorbents can be filled in the annular spaces, and the adsorption barrel is composed of a pore plate or a grid.

Abstract: The present invention provides a method for simulating daylight performance of buildings based on regional daylight climate data. The method comprises the steps of: establishing a regional sky luminance distribution database from measured data; mapping sky luminance data to an artificial sky lamp group; using a 3D printing machine to fabricate a scaled physical model based on real parameters of the building to be simulated; and using the scaled physical model in the artificial sky integrated with regional sky luminance distribution data to make the daylight performance simulation. This method can achieve high-precision simulation of the daylight performance of buildings by using regional sky daylight climate data with a highly accurate physical model of the building.

Abstract: The present invention proposes an evaluation method of solar energy utilization potential in urban high-density areas based on low-altitude photogrammetry, comprising the following steps: low-altitude data acquisition using drones, acquisition of three-dimensional point cloud data, screening of building subject points, selection of seed region, region growth and point cloud patch segmentation, three-dimensional reconstruction, building geometry model, solar radiation simulation and solar energy utilization potential assessment steps. The invention utilizes low-altitude photogrammetry to obtain point cloud data in a high-density area of the city, and performs semantic division and three-dimensional reconstruction on the point cloud data through a parameterization tool to obtain a singular geometric model. Therefore, the solar radiation and dynamic change obtained from the roof and facade of the building are simulated and analyzed in the same platform.

Abstract: The present invention provides a method for simulating daylight performance of buildings based on regional daylight climate data. The method comprises the steps of: establishing a regional sky luminance distribution database from measured data; mapping sky luminance data to an artificial sky lamp group; using a 3D printing machine to fabricate a scaled physical model based on real parameters of the building to be simulated; and using the scaled physical model in the artificial sky integrated with regional sky luminance distribution data to make the daylight performance simulation. This method can achieve high-precision simulation of the daylight performance of buildings by using regional sky daylight climate data with a highly accurate physical model of the building.

Abstract: The present invention proposes an evaluation method of solar energy utilization potential in urban high-density areas based on low-altitude photogrammetry, comprising the following steps: low-altitude data acquisition using drones, acquisition of three-dimensional point cloud data, screening of building subject points, selection of seed region, region growth and point cloud patch segmentation, three-dimensional reconstruction, building geometry model, solar radiation simulation and solar energy utilization potential assessment steps. The invention utilizes low-altitude photogrammetry to obtain point cloud data in a high-density area of the city, and performs semantic division and three-dimensional reconstruction on the point cloud data through a parameterization tool to obtain a singular geometric model. Therefore, the solar radiation and dynamic change obtained from the roof and facade of the building are simulated and analyzed in the same platform.