专利技术和专有技术
申能科技拥有(含独占许可获得)70余件专利技术及其相关配套的专有技术, 覆盖机组蒸汽氧化及固体颗粒侵蚀防治系列技术、直流锅炉蒸汽加热启动和稳燃技术、 回转式空预器全向柔性密封技术、零能耗脱硫技术、广义回热系列技术、节能型全天候脱硝技术、 集中式变频供电技术、高温亚临界技术、全负荷低氧低氮稳燃技术、以及高低位分轴布置技术。 同时,公司还根据国内外机组现状和用户的需求,正在不断研发新的节能环保技术。
冯总典型的论文
This engineering study demonstrates the feasibility and advantages of a cross compound unit with an elevated and conventional turbine layout.
Existing materials and equipment manufacturing capabilities were used to design a double reheat unit using the elevated and conventional turbine layout with other mature energysaving systems to achieve a net efficiency of 48.92%.
The development of conventional coal-fired power plants is reviewed to describe the existing bottlenecks in highefficiency Super Critical (SC) and Ultra Super Critical (USC) electrical generation units.
The development of 700℃ Advanced Ultra Super Critical (A-USC) units has been much slower than expected mainly due to the material limitations. Double reheat systems increase efficiency but also significantly increase cost and complexity.
This design reduces the use of expensive high-temperature materials, with significantly lower piping costs as well as lower pressure drops and heat losses which increase the efficiency and the performance-price ratio.
Key Words: low CO2, kg/MWh, gross, clean, Advanced Ultra Super Critical (A-USC), Ultra Super Critical (USC), efficiency improvements, cross compound, elevated and conventional turbine layout, double reheat.
This engineering study demonstrates the feasibility and advantages of a cross compound unit with an elevated and conventional turbine layout.
Existing materials and equipment manufacturing capabilities were used to design a double reheat unit using the elevated and conventional turbine layout with other mature energysaving systems to achieve a net efficiency of 48.92%.
The development of conventional coal-fired power plants is reviewed to describe the existing bottlenecks in highefficiency Super Critical (SC) and Ultra Super Critical (USC) electrical generation units.
The development of 700℃ Advanced Ultra Super Critical (A-USC) units has been much slower than expected mainly due to the material limitations. Double reheat systems increase efficiency but also significantly increase cost and complexity.
This design reduces the use of expensive high-temperature materials, with significantly lower piping costs as well as lower pressure drops and heat losses which increase the efficiency and the performance-price ratio.
Key Words: low CO2, kg/MWh, gross, clean, Advanced Ultra Super Critical (A-USC), Ultra Super Critical (USC), efficiency improvements, cross compound, elevated and conventional turbine layout, double reheat.
This engineering study demonstrates the feasibility and advantages of a cross compound unit with an elevated and conventional turbine layout.
Existing materials and equipment manufacturing capabilities were used to design a double reheat unit using the elevated and conventional turbine layout with other mature energysaving systems to achieve a net efficiency of 48.92%.
The development of conventional coal-fired power plants is reviewed to describe the existing bottlenecks in highefficiency Super Critical (SC) and Ultra Super Critical (USC) electrical generation units.
The development of 700℃ Advanced Ultra Super Critical (A-USC) units has been much slower than expected mainly due to the material limitations. Double reheat systems increase efficiency but also significantly increase cost and complexity.
This design reduces the use of expensive high-temperature materials, with significantly lower piping costs as well as lower pressure drops and heat losses which increase the efficiency and the performance-price ratio.
Key Words: low CO2, kg/MWh, gross, clean, Advanced Ultra Super Critical (A-USC), Ultra Super Critical (USC), efficiency improvements, cross compound, elevated and conventional turbine layout, double reheat.
This engineering study demonstrates the feasibility and advantages of a cross compound unit with an elevated and conventional turbine layout.
Existing materials and equipment manufacturing capabilities were used to design a double reheat unit using the elevated and conventional turbine layout with other mature energysaving systems to achieve a net efficiency of 48.92%.
The development of conventional coal-fired power plants is reviewed to describe the existing bottlenecks in highefficiency Super Critical (SC) and Ultra Super Critical (USC) electrical generation units.
The development of 700℃ Advanced Ultra Super Critical (A-USC) units has been much slower than expected mainly due to the material limitations. Double reheat systems increase efficiency but also significantly increase cost and complexity.
This design reduces the use of expensive high-temperature materials, with significantly lower piping costs as well as lower pressure drops and heat losses which increase the efficiency and the performance-price ratio.
Key Words: low CO2, kg/MWh, gross, clean, Advanced Ultra Super Critical (A-USC), Ultra Super Critical (USC), efficiency improvements, cross compound, elevated and conventional turbine layout, double reheat.
This engineering study demonstrates the feasibility and advantages of a cross compound unit with an elevated and conventional turbine layout.
Existing materials and equipment manufacturing capabilities were used to design a double reheat unit using the elevated and conventional turbine layout with other mature energysaving systems to achieve a net efficiency of 48.92%.
The development of conventional coal-fired power plants is reviewed to describe the existing bottlenecks in highefficiency Super Critical (SC) and Ultra Super Critical (USC) electrical generation units.
The development of 700℃ Advanced Ultra Super Critical (A-USC) units has been much slower than expected mainly due to the material limitations. Double reheat systems increase efficiency but also significantly increase cost and complexity.
This design reduces the use of expensive high-temperature materials, with significantly lower piping costs as well as lower pressure drops and heat losses which increase the efficiency and the performance-price ratio.
Key Words: low CO2, kg/MWh, gross, clean, Advanced Ultra Super Critical (A-USC), Ultra Super Critical (USC), efficiency improvements, cross compound, elevated and conventional turbine layout, double reheat.