This monitoring system is applicable to all scenarios requiring real-time, mobile monitoring of greenhouse gases, including but not limited to:

1. Urban Environmental Monitoring: Cities contain various pollution sources, such as congested roads, industrial areas, etc.
2. Chemical and Industrial Parks: Mobile monitoring can flexibly conduct inspections within the parks, quickly locate emission sources, assess emission intensity, and facilitate corresponding emission reduction measures.
3. Livestock and Agricultural Production Areas: Including farmland, farms, and large pastures.
4. Landfills: The decomposition process of waste produces greenhouse gases such as methane. Mobile monitoring can track gas emissions from landfills and assess their impact on the surrounding environment.
5. Transportation Hubs: Such as ports, train stations, airports, etc., where the concentration of numerous vehicles leads to increased greenhouse gas emissions.
6. Nature Reserves: Mobile monitoring can track changes in the surrounding environment and assess the potential impact of human activities on protected areas.
7. Specific Event Sites: For example, large gatherings, music festivals, sports events, etc., where dense crowds and related activities may cause a short-term increase in greenhouse gas emissions.
8. Large Wastewater Treatment Plants: The wastewater treatment process also generates greenhouse gases. Using a high-precision greenhouse gas monitoring system, accurate data on greenhouse gas emissions and emission factors from wastewater treatment plants can be obtained, providing a basis for assessing their environmental impact and implementing emission reduction measures.

Haixin Xinyong Zhice The investment in a new energy mobile carbon monitoring system is necessary. It not only improves the precision of carbon monitoring station site selection, reduces deployment costs, but also collaborates with satellite observations to achieve air-ground validation, enhancing the accuracy of carbon emission accounting and providing technical support for urban peak carbon action.

1.   Improve the precision of high-precision carbon monitoring station site selection:

According to reports from the Ministry of Ecology and Environment, the pilot work on carbon monitoring and assessment has achieved certain results. Through comprehensive monitoring using "satellites + drones + mobile patrols," the comprehensiveness and accuracy of accounting for unorganized CH4 emissions during production processes can be enhanced. This indicates that mobile monitoring technology can provide preliminary high-precision carbon data collection and analysis for carbon monitoring station site selection, thereby improving precision and reducing investment waste due to improper site selection.

2.   Collaborate with satellite observations to achieve air-ground validation:

The mobile carbon monitoring system can integrate with satellite remote sensing technology to achieve three-dimensional monitoring of greenhouse gases. This integrated "sky-air-ground" carbon monitoring platform provides comprehensive, real-time, and three-dimensional tracking monitoring, offering a basis for carbon emission verification, assessment, and accounting. This approach can reduce inaccuracies in carbon monitoring data caused by site selection errors and improve the reliability of monitoring data.

3.   Reduce the deployment costs of carbon monitoring stations:

Traditional carbon monitoring station deployment incurs high costs, and once a location is selected, it becomes a fixed investment. In contrast, the mobile patrol monitoring system offers high flexibility, allowing data collection at different locations, thereby reducing additional costs due to improper fixed-site selection.

4.    Support urban peak carbon action:

Leveraging the existing ambient air monitoring network, expanding to build an integrated urban carbon monitoring network, and exploring "dual carbon" inversion assessment based on actual measurements can support key cities in achieving both air quality standards and CO2 peak targets ("dual achievement").

5.   Enhance the accuracy of carbon emission accounting:

The mobile carbon monitoring system can directly serve hotspot monitoring for carbon emission surveillance, improving the comprehensiveness and accuracy of accounting, particularly in pilot monitoring practices for coal mining and oil and gas extraction.

6.   Haixin's mature technology, promising pilot before promotion:

Haixin's new energy carbon monitoring mobile patrol vehicle technology is relatively mature. The system is entirely powered by electric vehicles, eliminating interference from vehicle exhaust. It is expected to gradually expand its application through a pilot-then-promotion approach, providing crucial support for carbon emission trading.

7.   Environmental management and pollution control:

Through high-precision monitoring and data analysis, pollution sources can be accurately located, such as methane leaks in landfills or abnormal greenhouse gas emissions in chemical zones. This provides a basis for the formulation and implementation of environmental protection policies.

8.    Policy formulation and implementation:

Monitoring data can assist in formulating and evaluating environmental policies, such as the "Air Pollution Prevention and Control Action Plan," ensuring policy effectiveness and scientific rigor. Management authorities can rationally plan enterprise layouts and strengthen supervision in high-emission areas.

9.    Environmental risk prevention and emergency response:

The system can promptly detect potential environmental risks, such as greenhouse gas leaks at energy extraction and processing sites, thereby preventing possible environmental incidents, such as large-scale leaks.

10.   Actively promote green development to achieve political performance:

Applying the monitoring system in landfills, chemical zones, and residential areas enables green operations, controls pollution, reduces emissions, achieves synergy between environmental protection and the economy, and demonstrates governance wisdom. By monitoring and controlling harmful gases, optimizing processes to improve energy efficiency, promoting urban sustainability, improving air quality to protect public health, gaining public support, and achieving outstanding political performance, it contributes to long-term development.

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