Smart Photovoltaic Energy-Visualization of Park Photovoltaic Power Generation Energy Management and Control

Foreword

If green is the essence of sustainable urban development, and wisdom is the brain that leads urban development, then green smart buildings should be the backbone of the future of urban ecology.

The smart park uses various information technologies and innovative concepts to open up and integrate the various systems in the park to achieve in-depth information sharing and business collaboration. As an important component of a smart city, the sustainable development of a smart park is particularly important. The "14th Five-Year Plan" pointed out that vigorously develop new energy industries such as wind power and photovoltaics, promote clean, low-carbon and safe and efficient use of energy, and promote the green transformation of key industries and important fields. Under this trend, the use of various energy-saving and low-carbon new energy construction materials to realize a green, ecological and smart park is the future development direction.

Today, the HT Hightopo will be used to build a smart park photovoltaic power generation energy management and control visualization system. According to the current situation of the park, the characteristics of energy management, and the integration of energy management, the design is scientific and efficient, and the implementation is strong, which is in line with the park operation. Digital smart park solution for maintenance management. Provide a comprehensive real-time, perceptible and knowable energy monitoring and decision-making analysis platform for the park operation and maintenance personnel.

Effect display

This time, with a park as the background, the application scenarios of photovoltaic power generation in the park are simulated, the photovoltaic power generation process is simulated through animation effects, and the Internet of Things data is connected to realize the operation and maintenance monitoring of equipment.

HT supports multiple methods of model rendering. This case is to manually model the buildings and roads in the park in 3D, and output the OBJ format model, which is rendered by the HT engine to simulate and restore the overall situation of the park. It also supports importing BIM model files in IFC format to generate scenes, and supports rendering oblique photography model files in 3D Tiles format.

All of the above methods HT support superimposing 2D panels and animation effects for interaction, and users can customize them according to their own display needs. The engine comes with a mouse for rotation, translation, and zooming in and out operations. At the same time, it also supports cross-platform browsing, which can be easily opened by any mobile terminal. This is an advantage that the C-side platform does not have, and realizes the single-finger rotation, two-finger zoom, and three-finger pan operations of the touch screen device. It does not need to be cross-platform. And worry about the different interaction modes.

System Analysis

Through on-site framing photos, satellite images, CAD drawings and other materials, the park scene can be quickly built. The scene manually places photovoltaic points to truly restore the distribution effect of photovoltaic panels. Incorporating environmental simulation to embellish, using environmental simulation, the park season (spring, summer, autumn, winter), time (morning, noon, dusk, night), weather (sunny, cloudy, rain, snow, after snow) Switch freely. It can also be connected with weather system data to realize automatic switching of environmental simulation content based on actual weather data.

Photovoltaic power generation is greatly affected by environmental factors. Through the reduction simulation of environment and light, combined with power generation data, the energy efficiency of power generation can be better analyzed, and it can provide a basis for the operation and maintenance and decision-making of the park.

Park key indicators

Photovoltaic is a green energy source and has the characteristics of reducing greenhouse gas carbon dioxide (CO₂) emissions. According to statistics, it is assumed that the average daily power generation is 1000 kWh, the CO₂ emission reduction is about 785 kg, and the equivalent planting is about 156 trees.

The key indicators of the park are displayed through 2D visualization panels, the construction scale, photovoltaic information, and power generation information that users are concerned about are statistically displayed, and the electricity consumption information of each building is monitored. It can be updated in real time by docking with the real-time data in the background to display the statistics of the contribution made to energy saving and emission reduction.

Photovoltaic power generation process

Photovoltaic power generation is a technology that uses the photovoltaic effect of the semiconductor interface to directly convert light energy into electrical energy. It is mainly composed of solar panels (components), controllers and inverters. The main components are composed of electronic components. After the solar cells are connected in series, they can be packaged and protected to form a large-area solar cell module, and then combined with power controllers and other components to form a photovoltaic power generation device.

The scene is displayed in a sci-fi wireframe style, highlighting the equipment model, and expressing the whole process of photovoltaic conversion from light energy to electric energy, power supply to equipment, and energy storage through the flow of lines.

Charging pile operating status

To monitor the operating status and real-time power of the charging piles in the park, the charging status of the charging piles can be connected to determine whether there are vehicles in the current parking space, and the charging status can be simulated through the animation of the line flow effect. When the charging pile fails, the effect prompts such as model dyeing and warning animation are provided to facilitate the real-time use of the charging pile and operation monitoring and maintenance.

Cleaning robot demonstration

The cleaning robot can adapt to complex terrain and climatic environment, has a clean monitoring platform and a diagnostic system, remotely manages the photovoltaic power station, and can improve the automation of the power station. Water-free cleaning meets the cleaning problems of photovoltaic modules in large-area, long-distance, and multi-environment centralized photovoltaic power plants.

High temperature snow removal equipment

Through the three-dimensional management system, the start and stop control of the cleaning robot can be carried out, the operation of all robots in the park can be monitored, the animation of the robot cleaning is displayed, and the process of simulating the photovoltaic panel from dirty to clean after the robot is cleaned. As the photovoltaic panels are covered by snow due to the exposure of the photovoltaic panels outside the building, this problem can be avoided by the high-temperature snow removal equipment at the bottom of the photovoltaic panels. The whole process of high-temperature snow removal is also restored in the way of animation effects in the scene.

cleaning robot disassembly

The cleaning robot is composed of photovoltaic panels, brushes, motors, and battery packs. The pulleys walk along the frame of the module. The brushes used for cleaning rotate at a high speed, and the direction of rotation is opposite to the traveling direction of the walking wheels. The dust is dusted off the surface of the component, and then driven to the gap of the component under the combined action of the brush and the rotating airflow.

This case shows the internal structure of the robot in the form of equipment splitting and explosion, and the robot is split, supplemented by the change of shell transparency and edge streamer flow effect to increase the appreciation of the animation. It is more detailed by connecting the IoT data of the parts. View the current status of each component of the device in a minute, and realize the visualization of global monitoring from the macro to the micro.

Roaming inspection

HT supports roaming from the perspective of simulated drones or pedestrians, and can browse the park in all directions without blind spots. When passing the equipment, it automatically pops up information for viewing, which is convenient for operation and maintenance personnel to conduct inspections. Supports display combined with WebVR. By adapting to the VR device, users can wear VR glasses with the handle to walk and fly in the scene, and realize functions such as grabbing and moving the device through the handle. Compared with the traditional viewing method, it has a 360-degree panoramic picture, users can be immersed in the scene, fully experience the atmosphere and atmosphere, the sense of space and distance will be more layered, to achieve a truly immersive interaction.

summary

As the construction of smart parks continues to advance. Not only must the park construction, planning, management and public services be more precise, convenient, intelligent and efficient, and the park’s comprehensive development capability and safety management level must be enhanced, but also the sustainability of green ecological development must be emphasized, so that new energy and new technologies can be combined to achieve information The greater the value of technology.

Innovation and technology are playing an increasingly important role in various fields. The comprehensive application of advanced technologies such as GIS technology, big data, Internet of Things, and HT visualization has brought great value enhancement to the power, energy and other industries. The HT visualization application realizes data sharing, making the industry digital and green.

Based on years of project experience and solid visualization technical support, there are many excellent case realizations in wind power generation, offshore power stations, nuclear power plants, etc. Tupu Software is also implementing visualization solutions for outdoor large-scale photovoltaic power stations. You can pay attention Follow-up update~

You can go to the official website of Tupu Software to view more cases and effects:

https://www.hightopo.com/demos/index.html