Key Tasks Of Daily Glass Industry To Realise Carbon Peak Implementation

The decision to achieve carbon peak and carbon neutrality was made by the CPC Central Committee as a major strategic move to coordinate both domestic and international situations. The objective is to promote high-quality economic development and build a modern socialist country comprehensively. Light industry is an important sector of China's national economy and plays a critical role in meeting people's needs, developing a circular economy, promoting green consumption, and reducing carbon footprints. As such, this industry bears the responsibility of facilitating carbon reduction, promoting environmentally-friendly production, and encouraging low-carbon lifestyles both in industrial and consumption fields.

In light of this, the China Light Industry Federation developed and released an Implementation Plan for Carbon Peak in Key Areas of Light Industry. The plan seeks to support the implementation of the decision-making and deployment of the Party Central Committee and The State Council towards accelerating the process of achieving a green and low-carbon transformation of light industry.

key task for Daily glass industry: 
2. Prioritize the use of clean energy to optimize the fuel structure. To promote this, high-quality coal with low sulfur and ash content (W0.5% and W10%, respectively) should be selected for gasification through the pipeline combustion process. Additionally, coal substitution should be encouraged in areas where conditions permit. Glass kilns in regions with abundant power resources should consider natural gas + electric explosion as an energy structure, and smaller production scale products with higher added value should employ full electric melting technology or natural gas + oxygen combustion technology. The development of hydrogen energy should also be considered, paying attention to the prospect and practical application of hydrogen or hydrogen-doped combustion technology in the daily glass industry. Clean energy with high calorific value, low sulfur, and low ash content should also be prioritized.

In order to promote green development and technological progress, extensive research should be conducted on the key green manufacturing technologies. An optimization of the raw material structure should take place in order to improve low-carbon formula. Moreover, focusing on the glass melting mechanism and technology will be essential, as stunning innovations could emerge from this area. To achieve this, one should invest in computer simulation of furnace thermal system software development, and research and development of glass materials to improve product quality, optimize performance, fusible, energy saving and environmental protection should be taken up. Research projects may focus on the design, development, and technical application of energy-saving and environment-friendly glass kiln, including full electric melting, electric melting, oxygen combustion technology, NOx production concentration ^1000mg/m3, and low nitrogen combustion technology. In addition, DCS energy-saving automatic control technology of glass melting kiln, lightweight glass bottles (lightweight W1.0) manufacturing technology, development, and application of neutral 5.0 pharmaceutical borosilicate glass production technology, as well as development and application of manufacturing technology for glass-ceramics also require extensive attention. By engaging in these innovative projects, technology will be strengthened, and this will ensure sustainable and green development in the manufacturing sector.

To promote energy conservation and carbon reduction in the industry, it is essential to increase research and development of key equipment. The focus should be on accelerating the innovation and application of energy-saving and environmentally friendly glass kiln technologies such as full electric melting, electric assisted melting, and total oxygen combustion. Additionally, it is crucial to support the development and application of lightweight glass bottles and cans by investing in research and development of lightweight W1.0 equipment.

Moreover, there is a need to prioritize the research and development of glass molding equipment that offers reliable performance, stable operation, high control accuracy, high machine speed, and multi-station capabilities. This will enable efficient production processes and enhance manufacturing capabilities.

Another aspect to consider is the investment in equipment for product post-processing and deep processing. This includes the development of equipment for multi-color silk screen printing, spraying, laser blasting, and tempering. These advanced technologies will not only improve the aesthetic appeal of glass products but also increase their durability and functionality.

Furthermore, it is imperative to invest in equipment for environmental treatment to reduce pollutant emissions and enhance the comprehensive utilization of waste glass. This includes the development of technologies and equipment for the treatment of flue gas, as well as the intelligent management software to ensure real-time monitoring, emission concentration detection, parameter alarm, and intelligent analysis. These measures will contribute to the stable operation of green production processes.

In conclusion, by prioritizing research and development of key equipment, promoting energy conservation and carbon reduction in the glass industry can be effectively achieved. The focus should be on advancing technologies such as energy-efficient kilns, lightweight glass production, advanced glass molding equipment, post-processing technologies, and equipment for environmental treatment and waste utilization. These efforts will pave the way for a more sustainable and environmentally friendly glass industry.